RESONANCE-BASED WIRELESS POWER TRANSFER SYSTEM
First Claim
1. A resonance-based wireless power transfer system, comprising:
- a) a load;
b) a drive coil array, said drive coil comprising a number of driver coils, said driver coils injecting RF energy to maintain resonance in the presence of losses and power drawn by the load;
c) a transmitter coil array, said transmitter coil array comprising a number of transmitter coils magnetically coupled to said driver coil array, said transmitter coils having at least one resonant frequency and acting as an energy transmitter;
d) a receiver coil, said receiver coil having at least one resonant frequency, and capturing magnetic field produced by said transmitter coil array separated from said receiver coil acting as an energy receiver; and
e) a load coil, said load coil being magnetically coupled to said receiver coil for receiving RF energy;
whereinsaid transmitter coil array and said receiver coil have the same resonant frequency or frequencies, each pair of said driver coil and said transmitter coil forms a voltage step-up transformer to produce a strong resonance for wireless power delivery to said receiver coil within a body, and said load coil is operatively coupled to power said load.
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Accused Products
Abstract
A wireless power transfer system including a driver coil array, a hexagonally-packed transmitter mat, a receiver coil, and a load coil for powering a medical implant. The magnetically coupled resonance between two isolated parts is established by an array of primary coils and a single small secondary coil to create a transcutaneous power link for implanted devices as moving targets. The primary isolated part includes a driver coil array magnetically coupled to a mat of hexagonally packed primary coils. Power is injected by the driver coils into the transmitter coils in the transmitter mat to maintain resonance in the presence of losses and power drawn by the receiver coil from the magnetic field. The implanted secondary isolated part includes a receiver coil magnetically coupled to a load coil. A rectification/filter system is connected to the load coil supplying DC power to the electronic circuits of the implant.
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Citations
20 Claims
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1. A resonance-based wireless power transfer system, comprising:
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a) a load; b) a drive coil array, said drive coil comprising a number of driver coils, said driver coils injecting RF energy to maintain resonance in the presence of losses and power drawn by the load; c) a transmitter coil array, said transmitter coil array comprising a number of transmitter coils magnetically coupled to said driver coil array, said transmitter coils having at least one resonant frequency and acting as an energy transmitter; d) a receiver coil, said receiver coil having at least one resonant frequency, and capturing magnetic field produced by said transmitter coil array separated from said receiver coil acting as an energy receiver; and e) a load coil, said load coil being magnetically coupled to said receiver coil for receiving RF energy; wherein said transmitter coil array and said receiver coil have the same resonant frequency or frequencies, each pair of said driver coil and said transmitter coil forms a voltage step-up transformer to produce a strong resonance for wireless power delivery to said receiver coil within a body, and said load coil is operatively coupled to power said load. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20)
said transmitter coils are grouped standard hexagonal cells; said hexagonal cells comprise seven transmitter coils constructed by hexagonal PCBs (printed circuit board); and said transmitter mat generates uniform magnetic field for free-access wireless electricity via magnetically resonant coupling between said transmitter mat and said receiver coil as a moving target.
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3. The system of claim 1, wherein
said driver coil array comprises a number of hexagonal elements, each element consisting of seven loops; -
said seven loops are all connected in parallel to a pair of open coaxial conductor rings which are further connected to the output of an RF power amplifier; and a gap is made at each ring to avoid harmful loop current generated by an RF magnetic field.
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4. The system of claim 2, wherein said standard hexagonal cell is individually driven.
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5. The system of claim 1, wherein a target position tracking device is used to determine which said standard hexagonal cell or coils in said standard hexagonal cell are to transmit power.
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6. The system of claim 2, wherein a target position tracking device is used to determine which said standard hexagonal cell or coils in said standard hexagonal cell are to transmit power.
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7. The system of claim 3, wherein said elements are individually activated.
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8. The system of claim 1, wherein said receiver coil comprises two planar spiral sub-coils and a helical sub-coil, said three sub-coils wound in a proper directions to maximally capture the magnetic field produced by said transmitter coil array, and said sub-coils combined and connected to form said receiver coil with a shape resembling a shallow box.
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9. The system of claim 1, wherein said receiver coil serves as a component of the packaging material for an implant, and the exterior of said receiver coil is coated or covered by a biocompatible material for biological safety.
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10. The system of claim 1, wherein said receiver coil is cylindrical in shape in order to comply with exterior dimensions of an associated (parent) device that is cylindrical or circular in shape.
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11. The system of claim 1, wherein said receiver coil takes on a rectangular shape in order to correspond to associated devices of rectangular shape.
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12. The system of claim 1, wherein said load coil is magnetically coupled to said receiver coil for powering said load.
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13. The system of claim 1, wherein said load coil is placed within said receiver coil, allowing the minimization of device size.
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14. The system of claim 2, wherein PSCs are constructed in a front side by hexagonal PCBs, several conductor strips on a reverse side of each of said PCBs are utilized to form distributed capacitances with respect to said PSC on the front side.
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15. The system of claim 2, wherein each of said conductor strips covers only two adjacent tracks of said PSC, and each of said PCBs comprises a plurality of conductive strips to form distributed capacitances.
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16. The system of claim 2, wherein said transmitter coil is a circular spiral.
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17. The system of claim 2, wherein said transmitter coil is a square or rectangular spiral.
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18. The system of claim 2, wherein said transmitter coil is a fan-shape spiral.
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19. The system of claim 2, wherein conductor coils and/or conductive strips have a large surface area thereof plated with silver to provide for small electric resistance adapting to the skin effect of RF current.
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20. The system of claim 8, wherein said planar sub-coils are circular, rectangular, or hexagonal spiral.
Specification