Space-adaptive wireless power transfer system and method using evanescent field resonance

The invention claimed is: 1. A magnetic resonance wireless power transfer method, comprising: transferring power from a source coil to a transmitting (Tx) resonant coil using a magnetic induction method; transferring the power from the Tx resonant coil to a receiving (Rx) resonant coil, having a resonant frequency identical with that of the Tx resonant coil, via magnetically-coupled resonance of magnetic evanescent field with non-directive property; and transferring the power from the Rx resonant coil to a device coil of an electronic device using the magnetic induction method; wherein in order to transfer the power irrespective of directionality, the Tx resonant coil and the Rx resonant coil are arranged at a right angle or a specific angle of inclination relative to each other so that center axes of the Tx resonant coil and the Rx resonant coil are not parallel to each other, and wherein impedance matching at the source coil is performed by controlling the number of turns or size of the source coil or the interval between the source coil and the Tx resonant coil at a specific resonant frequency of the Tx resonant coil, or impedance matching at the device coil is performed by controlling the number of turns or size of the device coil or the interval between the device coil and the Rx resonant coil at the specific resonant frequency of the Rx resonant coil. 2. A magnetic resonance wireless power transfer method, comprising: transferring power from a source coil to a Tx resonant coil using a magnetic induction method; transferring the power from the Tx resonant coil to an intermediate resonant coil, having a resonant frequency identical with that of the Tx resonant coil, via magnetically-coupled resonance; transferring the power from the intermediate resonant coil to an Rx resonant coil, having a resonant frequency identical with the Rx resonant coil, via magnetically-coupled resonance; and transferring the power from the Rx resonant coil to a device coil of an electronic device using a magnetic induction method; wherein the intermediate resonant coil is placed at a right angle or an angle of inclination relative to the Tx resonant coil and the Rx resonant coil, and wherein impedance matching at the source coil is performed by controlling the number of turns or size of the source coil or the interval between the source coil and the Tx resonant coil at a specific resonant frequency of the Tx resonant coil. 3. A magnetic resonance wireless power transfer system, comprising: a source coil configured to be supplied with power from a source; a Tx resonant coil configured to be supplied with the power from the source coil using a magnetic induction method; and an Rx resonant coil configured to be supplied with the power from the Tx resonant coil at a resonant frequency identical with that of the Tx resonant coil via magnetically-coupled resonance of magnetic evanescent field with non-directive property, wherein in order to transfer the power irrespective of directionality, the Tx resonant coil and the Rx resonant coil are arranged at a right angle or a specific angle of inclination relative to each other so that center axes of the Tx resonant coil and the Rx resonant coil are not parallel to each other, and the Rx resonant coil transfers the power to a device coil of an electronic device using the magnetic induction method, and wherein impedance matching at the source coil is performed by controlling the number of turns or size of the source coil or the interval between the source coil and the Tx resonant coil at a specific resonant frequency of the Tx resonant coil, or impedance matching at the device coil is performed by controlling the number of turns or size of the device coil or the interval between the device coil and the Rx resonant coil at the specific resonant frequency of the Rx resonant coil. 4. The magnetic resonance wireless power transfer system as set forth in claim 3 , further comprising at least one of an impedance matching circuit between the source and the source coil, an impedance matching circuit between the device coil and a rectifier circuit of the electronic device, and an impedance matching circuit between the device coil and load of the electronic device. 5. The magnetic resonance wireless power transfer system as set forth in claim 3 , wherein at least one of the Tx resonant coil and the Rx resonant coil comprises: a lumped inductor or capacitor whose two electrodes are connected between both ends of the at least one coil, or whose only one electrode is connected to one of both ends of the at least one coil, to both ends of the at least one coil, or to an intermediate portion of the at least one coil. 6. The magnetic resonance wireless power transfer system as set forth in claim 3 , wherein the Tx resonant coil is embedded in a wall or a board, the Rx resonant coil is embedded in a desk or a table, a space, another wall, a pad, or a container near the wall, and the electronic device near the Rx resonant coil is supplied with the power. 7. The magnetic resonance wireless power transfer system as set forth in claim 3 , wherein the Tx resonant coil or the Rx resonant coil has a helical or spiral form. 8. The magnetic resonance wireless power transfer system as set forth in claim 4 , wherein the impedance matching circuit includes a coaxial cable to provide a capacitance value. 9. The magnetic resonance wireless power transfer system as set forth in claim 5 , wherein a sum of a capacitance of the at least one coil itself to which the capacitor is additionally coupled and a capacitance of the added capacitor is equal to or higher than 100 pF and equal to or lower than 10 nF. 10. The magnetic resonance wireless power transfer system as set forth in claim 7 , wherein the Tx resonant coil or the Rx resonant coil has a form in which a wire is wound around a magnetic body. 11. A magnetic resonance wireless power transfer system, comprising: a source coil configured to be supplied with power from a source; a Tx resonant coil configured to be supplied with the power from the source coil using a magnetic induction method; an intermediate resonant coil supplied with power from the Tx resonant coil at a resonant frequency identical with that of the Tx resonant coil using a magnetic resonance mechanism; and an Rx resonant coil configured to be supplied with the power from the intermediate resonant coil at a resonant frequency identical with that of the intermediate resonant coil via magnetically-coupled resonance, wherein the intermediate resonant coil is placed at a right angle or an angle of inclination relative to the Tx resonant coil and the Rx resonant coil, and the Rx resonant coil transfers the power to a device coil of an electronic device using a magnetic induction method, and wherein impedance matching at the source coil is performed by controlling the number of turns or size of the source coil or the interval between the source coil and the Tx resonant coil at a specific resonant frequency of the Tx resonant coil. 12. The magnetic resonance wireless power transfer system as set forth in claim 11 , wherein at least one of the Tx resonant coil, the Rx resonant coil, and the intermediate resonant coil comprises; a lumped inductor or a capacitor whose two electrodes are connected between both ends of the at least one coil, or whose only one electrode is connected to one of both ends of the at least one coil, to both ends of the at least one coil, or to an intermediate portion of the at least one coil. 13. The magnetic resonance wireless power transfer system as set forth in claim 11 , wherein the Tx resonant coil, the Rx reson