초록 ▼

An inductive power supply that maintains resonance and adjusts duty cycle based on feedback from a secondary circuit. A controller, driver circuit and switching circuit cooperate to generate an AC signal at a selected operating frequency and duty cycle. The AC signal is applied to the tank circuit t

An inductive power supply that maintains resonance and adjusts duty cycle based on feedback from a secondary circuit. A controller, driver circuit and switching circuit cooperate to generate an AC signal at a selected operating frequency and duty cycle. The AC signal is applied to the tank circuit to create an inductive field for powering the secondary. The secondary communicates feedback about the received power back to the primary controller. The power transfer efficiency may be optimized by maintaining the operating frequency substantially at resonance, and the amount of power transferred may be controlled by adjusting the duty cycle.

대표청구항 ▼

1. An inductive power supply for providing power wirelessly to a remote device, said inductive power supply comprising: a primary circuit for generating a signal at an operating frequency, said primary circuit being capable of adjusting a duty cycle of said signal to allow variation in an amount of

1. An inductive power supply for providing power wirelessly to a remote device, said inductive power supply comprising: a primary circuit for generating a signal at an operating frequency, said primary circuit being capable of adjusting a duty cycle of said signal to allow variation in an amount of power transferred to the remote device at said operating frequency;a tank circuit in electrical communication with said primary circuit, wherein said primary circuit applies said signal to said tank circuit to transfer an amount of power to said remote device;said inductive power supply configured to receive feedback from said remote device;said primary circuit being configured to control said operating frequency of said signal in response to said feedback to optimize power transfer efficiency between said inductive power supply and said remote device; andsaid primary circuit being configured to control said duty cycle of said signal in response to said feedback to control said amount of power transferred to said remote device at said operating frequency. 2. The inductive power supply of claim 1 wherein said primary circuit maintains said operating frequency of said signal substantially at resonance. 3. The inductive power supply of claim 1 wherein said primary circuit continuously adjusts said operating frequency to maintain substantial resonance and continuously adjusts said duty cycle based on a comparison between said amount of power transferred to said remote device and a threshold. 4. The inductive power supply of claim 1 wherein said primary circuit controls said duty cycle of said signal according to at least one of a battery charging profile and a demand by said remote device. 5. The inductive power supply of claim 1 wherein said primary circuit includes: a primary controller;a driver circuit in electrical communication with said primary controller;a switching circuit in electrical communication with said driver circuit; anda sensor for sensing reflected impedance of said remote device, wherein said sensor is in electrical communication with said tank circuit and said primary controller. 6. The inductive power supply of claim 5 wherein said switching circuit includes a pair of switches, wherein each switch is switched on at said duty cycle and at said operating frequency, but out of phase with each other; andwherein, in response to said feedback, said primary controller controls said operating frequency of each of said switches; andwherein, in response to said feedback, said primary controller controls said duty cycle of each of said switches. 7. The inductive power supply of claim 5 wherein said primary controller adjusts said operating frequency of said signal as a function of input from said sensor. 8. The inductive power supply of claim 1 wherein said primary circuit includes a wireless receiver for receiving said feedback from said remote device. 9. An inductive power supply system comprising: an inductive power supply including: a primary circuit for generating a signal at an operating frequency and for adjusting a duty cycle of said signal to control an amount of power transferred at said operating frequency; anda tank circuit in electrical communication with said primary circuit, wherein said primary circuit applies said signal to said tank circuit to transfer an amount of power to said remote device;said inductive power supply configured to receive feedback from said remote device;a remote device separable from said inductive power supply for receiving power from said inductive power supply, said remote device including: a secondary energized by said inductive field,a load in electrical communication with said secondary,a sensor in electrical communication with said secondary,a secondary controller in electrical communication with said sensor, anda communication device in electrical communication with said secondary controller for sending feedback to said inductive power supply;wherein, in response to said feedback, said primary circuit controls said operating frequency of said signal to optimize power transfer efficiency between said inductive power supply and said remote device; andwherein, in response to said feedback, said primary circuit controls said duty cycle of said signal to control said amount of power transferred to said remote device at said operating frequency. 10. The inductive power supply system of claim 9 wherein said primary circuit maintains said operating frequency of said signal substantially at resonance. 11. The inductive power supply system of claim 9 wherein said primary circuit continuously adjusts said operating frequency to maintain substantial resonance and continuously adjusts said duty cycle based on a comparison between said amount of power transferred to said remote device and a threshold. 12. The inductive power supply system of claim 9 wherein said primary circuit controls said duty cycle of said signal according to at least one of a battery charging profile and a demand communicated to said inductive power supply by said remote device. 13. The inductive power supply system of claim 9 wherein said primary circuit includes: a primary controller;a driver circuit in electrical communication with said primary controller;a switching circuit in electrical communication with said driver circuit; anda sensor for sensing reflected impedance of said remote device, wherein said sensor is in electrical communication with said tank circuit and said primary controller. 14. The inductive power supply system of claim 13 wherein said switching circuit includes a pair of switches, wherein each switch is switched at said duty cycle and at said operating frequency, but out of phase with each other; andwherein, in response to said feedback, said primary controller controls said operating frequency of each of said switches; andwherein, in response to said feedback, said primary controller controls said duty cycle of each of said switches. 15. The inductive power supply system of claim 13 wherein said primary controller adjusts said operating frequency of said signal as a function of input from said sensor. 16. The inductive power supply system of claim 9 wherein said primary circuit includes a wireless receiver and said remote device includes a wireless transmitter, wherein said wireless receiver receives said feedback from said wireless transmitter. 17. A method for transferring power from an inductive power supply to a remote device, said method comprising: setting an initial operating frequency of a signal in the inductive power supply;setting an initial duty cycle of the signal to set an initial power level in the inductive power supply;applying the signal to a tank circuit for transferring an amount of power from the inductive power supply to a remote device;receiving, in the inductive power supply, feedback from the remote device;adjusting, in response to the feedback, the operating frequency of the signal to optimize power transfer efficiency between the inductive power supply and the remote device;adjusting, in response to the feedback, the duty cycle of the signal to control the amount of power transferred to the remote device. 18. The method for transferring power of claim 17 wherein said step of adjusting the duty cycle includes: decreasing the duty cycle of the signal in response to a determination that the power transferred to the remote device is above a threshold; andincreasing the duty cycle of the signal in response to a determination that the power transferred to the remote device is below a threshold. 19. The method for transferring power of claim 17 wherein at least one of said setting an initial operating frequency and adjusting said operating frequency includes sweeping a frequency range, determining an amount of power transferred to the remote device for each operating frequency, and selecting an operating frequency where the amount of power transferred to the remote device is relatively high compared to other frequencies within the frequency range. 20. The method for transferring power of claim 17 wherein at least one of said setting an initial operating frequency and adjusting said operating frequency includes sweeping a frequency range and selecting the operating frequency closest to resonance. 21. The method for transferring power of claim 17 wherein said adjusting of the operating frequency includes continuously adjusting the operating frequency to maintain substantial resonance and said adjusting of the duty cycle includes continuously adjusting the duty cycle based on a comparison between the amount of power transferred to the remote device and a threshold. 22. The method for transferring power of claim 17 wherein said adjusting the duty cycle includes adjusting the duty cycle according to at least one of a battery charging profile and a demand by the remote device. 23. An inductive power supply for a remote device comprising: a tank circuit;a primary circuit in electrical communication with said tank circuit, said primary circuit configured to apply a signal to said tank circuit; anda receiver configured to receive communications from the remote device, said receiver in electrical communication with said primary circuit, said primary circuit configured to selectively adjust an operating frequency of said signal as a function of said communications to optimize power transfer efficiency from said tank circuit to the remote device, said primary circuit configured to selectively adjust a duty cycle of said signal as a function of said communications to control an amount of power transferred to the remote device at said operating frequency, whereby said inductive power supply maintains power transfer efficiency through operating frequency adjustments and while maintaining appropriate power level though duty cycle adjustments. 24. The inductive power supply of claim 23 wherein said receiver is further defined as a current sensor electrically coupled to said tank circuit to provide a signal indicative of current in said tank circuit. 25. The inductive power supply of claim 23 wherein said receiver is further defined as a communication receiver. 26. A method for wirelessly supplying power to a remote device, comprising the steps of: placing a remote device in sufficient proximity to an inductive power supply to establish an inductive coupling between the remote device and the inductive power supply;in the inductive power supply, applying a signal to a tank circuit at a plurality of different operating frequencies to wirelessly transfer power to the remote device;in the remote device, taking separate measurements of a characteristic of the power wirelessly received from the inductive power supply for each of said different operating frequencies;determining an initial operating frequency based on the separate measurements; andin the inductive power supply, applying a signal to the tank circuit at the initial operating frequencyreceiving, in the inductive power supply, communication from the remote device;adjusting, in response to the communication, the operating frequency of the signal to optimize power transfer efficiency between the inductive power supply and the remote device; andadjusting, in response to the communication, the duty cycle of the signal to control the amount of power transferred to the remote device. 27. The method of claim 26 wherein said determining step includes storing information indicative of a power transfer efficiency at each of the plurality of different operating frequencies; and selecting the initial operating frequency as the operating frequency having the greatest power transfer efficiency. 28. The method of claim 26 wherein said determining step includes storing information indicative of the operating frequency having the greatest power transfer efficiency; and selecting the initial operating frequency as the operating frequency having the greatest power transfer efficiency. 29. The method of claim 26 wherein the step of applying a signal to the tank circuit includes applying the signal at a first power level selected to be low enough not to risk over-powering the remote device. 30. The method of claim 26 wherein the step of applying a signal to the tank circuit includes applying the signal at a duty cycle selected to be low enough not to risk over-powering the remote device. 31. The inductive power supply of claim 1 further including a first controller to control said operating frequency and a second controller to control said duty cycle. 32. The inductive power supply of claim 1 further including a memory storing information relating to operating parameters of a plurality of remote devices. 33. The inductive power supply of claim 10 wherein said information includes for each of the remote devices at least one of a resonant frequency, a maximum operating frequency, a minimum operating frequency, a current usage, a minimum duty cycle, a maximum duty cycle and wireless communication protocol of the remote device. 34. The method of claim 26 further comprising the step of determining an initial duty cycle based on the separate measurements. 35. The method of claim 26 further comprising the step of selecting an initial duty cycle of at or less than 20% so that too much power is not delivered to the remote device.