Three-coil topology for wireless power transfer

US 9,281,119 B2
Filed: 11/13/2013
Issued: 03/08/2016
Est. Priority Date: 11/13/2013
Status: Active Grant

First Claim

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1. A wireless power transfer system comprising a power-transmitting unit and a power-receiving unit, the power-transmitting unit being configured to wirelessly transmit power in the wireless power transfer system, wherein:

the power-transmitting unit comprises;

an alternating-current (AC) power source;

a primary resonator comprising a primary coil, the primary resonator being electrically coupled to the power source such that a primary-coil current flows through the primary coil when the primary resonator is excited by the power source; and

a repeater resonator comprising a repeater coil end-to-end adjacent to the primary coil, the repeater resonator being electrically isolated from the power source, wherein the repeater coil and the primary coil are separated by a distance selected, and the repeater coil is configured, to amplify the primary-coil current by inductively generating a repeater-coil current that flows through the repeater coil and that is substantially greater than the primary-coil current;

so that when wirelessly transmitting the power, the power-transmitting unit generates a magnetic field for wireless power transfer with contribution from both the primary-coil current and the repeater-coil current while the power source is not required to provide a terminal voltage across the repeater coil to sustain the repeater-coil current, which is a current substantially greater than the primary-coil current, thereby discouraging occurrence of voltage stress at the power source;

the power-receiving unit comprises a receiver resonator, the receiver resonator comprising a receiver coil configured to receive the magnetic field so as to inductively generate a receiver-coil current that flows through the receiver coil for feeding to a load; and

the repeater coil is positioned such that the selected distance between the repeater coil and the primary coil is at most one third of a distance between the primary coil and the receiver coil.

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Abstract

A system using a three-coil topology for wireless power transfer is disclosed. The system comprises a primary resonator coupled to a power source, a repeater resonator and a receiver resonator. The primary resonator has a primary coil, and the repeater resonator has a repeater coil adjacent to the primary coil. The repeater coil and the primary coil are separated by a distance selected, and the repeater coil is configured, to amplify a primary-coil current by inductively generating a repeater-coil current that is substantially greater than the primary-coil current. A magnetic field contributed from both the primary-coil current and the repeater-coil current is generated while the power source needs not provide a terminal voltage across the repeater coil, thereby discouraging occurrence of voltage stress at the power source. The receiver resonator has a receiver coil, which receives the magnetic field to inductively generate a receiver-coil current for feeding to a load.

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16 Claims

1. A wireless power transfer system comprising a power-transmitting unit and a power-receiving unit, the power-transmitting unit being configured to wirelessly transmit power in the wireless power transfer system, wherein:
- the power-transmitting unit comprises;
  
  an alternating-current (AC) power source;
  
  a primary resonator comprising a primary coil, the primary resonator being electrically coupled to the power source such that a primary-coil current flows through the primary coil when the primary resonator is excited by the power source; and
  
  a repeater resonator comprising a repeater coil end-to-end adjacent to the primary coil, the repeater resonator being electrically isolated from the power source, wherein the repeater coil and the primary coil are separated by a distance selected, and the repeater coil is configured, to amplify the primary-coil current by inductively generating a repeater-coil current that flows through the repeater coil and that is substantially greater than the primary-coil current;
  
  so that when wirelessly transmitting the power, the power-transmitting unit generates a magnetic field for wireless power transfer with contribution from both the primary-coil current and the repeater-coil current while the power source is not required to provide a terminal voltage across the repeater coil to sustain the repeater-coil current, which is a current substantially greater than the primary-coil current, thereby discouraging occurrence of voltage stress at the power source;
  
  the power-receiving unit comprises a receiver resonator, the receiver resonator comprising a receiver coil configured to receive the magnetic field so as to inductively generate a receiver-coil current that flows through the receiver coil for feeding to a load; and
  
  the repeater coil is positioned such that the selected distance between the repeater coil and the primary coil is at most one third of a distance between the primary coil and the receiver coil.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
- - 2. The power-transmitting unit of claim 1, wherein the primary resonator has a resonant frequency substantially similar to the repeater resonator'"'"'s resonant frequency.
  - 3. The power-transmitting unit of claim 1, wherein the power source is configured to provide AC voltage having a frequency in the range from 100 kHz to 1 MHz.
  - 4. The wireless power transfer system of claim 1, wherein the primary resonator, the repeater resonator and the receiver resonator have substantially-similar resonant frequencies.
  - 5. The wireless power transfer system of claim 1, wherein a transfer efficiency achieved by the wireless power transfer system is greater than 85% when the repeater coil and the receiver coil are separated by a distance of 0.6 m.
  - 6. The wireless power transfer system of claim 1, wherein power wirelessly transferred from the power-transmitting unit to the power-receiving unit is at least 180 W.
  - 7. The wireless power transfer system of claim 1, wherein the power-receiving unit further comprises one or more rectifiers such that AC power provided from the receiver-coil current is rectified to direct-current (DC) power before feeding to the load.
  - 8. The wireless power transfer system of claim 7, wherein the load is one or more batteries configured to receive the DC power for recharging.
  - 9. The wireless power transfer system of claim 1 wherein the power-transmitting unit and the power-receiving unit are arranged such that the repeater coil and the receiver coil are relaxed from being axially substantially-aligned.
  - 10. The wireless power transfer system of claim 1, wherein the power-transmitting unit and the power-receiving unit are arranged such that an angular displacement between the repeater coil and the receiver coil is present.

11. A method for wirelessly transmitting power from a transmitting side to a receiving side, the transmitting side having a primary resonator, a repeater resonator and an alternating-current (AC) power source, the primary resonator comprising a primary coil, the repeater resonator comprising a repeater coil, the receiving side having a receiver resonator which comprises a receiver coil, the method comprising:
- positioning the primary coil to be end-to-end adjacent to the repeater coil;
  
  electrically isolating the repeater resonator from the power source;
  
  exciting the primary resonator by the power source to generate a primary-coil current flowing through the primary coil;
  
  selecting a distance between the repeater coil and the primary coil such that the primary-coil current inductively generates a repeater-coil current that flows through the repeater coil and that is substantially greater than the primary-coil current, so that the transmitting side is enabled to generate a magnetic field with contribution from both the primary-coil current and the repeater-coil current while the power source is not required to provide a terminal voltage across the repeater coil to sustain the repeater-coil current, which is a current substantially greater than the primary-coil current, to thereby discourage occurrence of voltage stress at the power source, wherein the selected distance between the repeater coil and the primary coil is at most one third of a distance between the primary coil and the receiver coil; and
  
  receiving the magnetic field by the receiver coil so as to inductively generate a receiver current that flows through the receiver coil for feeding to a load at the receiving side.
- View Dependent Claims (12, 13, 14, 15, 16)
- - 12. The method of claim 11, wherein the primary resonator, the repeater resonator and the receiver resonator have substantially-similar resonant frequencies.
  - 13. The method of claim 11, wherein the power source is configured to provide AC voltage having a frequency in the range from 100 kHz to 1 MHz.
  - 14. The method of claim 11, wherein a transfer efficiency in wirelessly transmitting power from the transmitting side to the receiving side is greater than 85% when the repeater coil and the receiver coil are separated by a distance of 0.6 m.
  - 15. The method of claim 11, wherein power wirelessly transferred from the transmitting side to the receiving side is at least 180 W.
  - 16. The method of claim 11, further comprising:
    - rectifying, at the receiver side, AC power provided from the receiver-coil current to direct-current (DC) power before feeding to the load.

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Current Assignee
Hong Kong Polytechnic University
Original Assignee
Hong Kong Polytechnic University
Inventors
Ni, Bailian, Chung, Chi-yung, Chan, Hon-lung
Primary Examiner(s)
Siek, Vuthe

Application Number

US14/079,577
Publication Number

US 20150130407A1
Time in Patent Office

846 Days
Field of Search

320/108
US Class Current

1/1
CPC Class Codes

H01F 38/14   Inductive couplings for wir...

H02J 50/12   of the resonant type

H02J 50/50   using additional energy rep...

Three-coil topology for wireless power transfer

First Claim

1 Assignment

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Abstract

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16 Claims

Specification

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Three-coil topology for wireless power transfer

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

6 Citations

16 Claims

Specification

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Use Cases

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Others