KR20140073416A - Method and apparatus for transceiving wireless power - Google Patents

Abstract

Disclosed are a method and an apparatus for transceiving wireless power. An apparatus for transceiving wireless power according to an embodiment includes at least one magnetostriction resonator which is excited by a magnetic field and at least one conversion coil which is located around the at least magnetostriction resonator. The least one conversion coil changes mechanical energy generated by the excitation of the least one magnetostriction resonator into electric energy.

Description

Field of the Invention [0001] The present invention relates to a wireless power transmitting /

The following embodiments relate to a wireless power transceiver and method.

Research on wireless power transmission has begun to overcome the inconveniences of wired power supply due to explosive increase of various electric devices including portable devices and limitations of existing battery capacity. One of the wireless power transmission techniques utilizes the resonance characteristics of the RF components. A wireless power transmission system using resonance characteristics may include a wireless power transmission device that supplies power and a wireless power reception device that is powered.

A wireless power transceiver according to one embodiment includes at least one magnetostrictive resonator excited by a magnetic field; At least one soft magnetic material positioned around the at least one magnetostrictive resonator; And at least one magnetostrictive resonator or at least one transducing coil located around the at least one soft magnetic material material.

The at least one conversion coil may convert mechanical energy generated by excitation of the at least one magnetostrictive resonator to electrical energy.

The at least one magnetostrictive resonator and the at least one soft magnetic material material may be in the form of a rod.

The at least one magnetostrictive resonator and the at least one soft magnetic material may be located within a distance less than the length of the at least one magnetostrictive resonator.

Wherein said at least one conversion coil and said at least one magnetostrictive resonator are located within a distance less than the length of said at least one magnetostrictive resonator, Lt; RTI ID = 0.0 > of soft magnetic material < / RTI >

The at least one soft magnetic material material may be a high-permeability ferrite rod.

The at least one magnetostrictive resonator and the at least one soft magnetic material material may be aligned in a line.

The at least one magnetostrictive resonator may be in the form of a tube-like rod and may be composed of a magnetostrictive ferrite material.

The at least one magnetostrictive resonator has a circular remanent magnetization and can be oscillated in a torsional vibrational mode as it is excited by the magnetic field.

The at least one magnetostrictive resonator and the at least one soft magnetic material material may have a cylindrical dimension.

The at least one magnetostrictive resonator and the at least one soft magnetic material material may be positioned parallel to each other in this dimensional or three dimensional arrangement.

The at least one magnetostrictive resonator may have the same resonant frequency.

A wireless power transceiver according to one embodiment includes at least two magnetostrictive resonators excited by a magnetic field; And at least one conversion coil located around the at least two magnetostrictive resonators.

The at least one conversion coil may convert mechanical energy generated by excitation of the at least two magnetostrictive resonators into electrical energy.

The at least two magnetostrictive resonators may be in the form of a rod.

The at least one conversion coil and the at least two magnetostrictive resonators may be located within a distance less than the length of the at least two magnetostrictive resonators.

The at least two magnetostrictive resonators have a circular residual magnetization, and can oscillate in a torsional vibration manner as they are excited by the magnetic field.

The at least two magnetostrictive resonators may be aligned in a line within a distance less than the length of the at least two magnetostrictive resonators.

The at least two magnetostrictive resonators may be parallelly aligned within a distance less than the length of the at least two magnetostrictive resonators.

The at least two magnetostrictive resonators may be positioned parallel to each other in this dimensional arrangement or three-dimensional arrangement.

The at least two magnetostrictive resonators may have the same resonant frequency.

A method of matching a wireless power transmission device comprising at least one magnetostrictive resonator and at least one conversion coil according to an embodiment comprises the steps of measuring the magnitude of the power transmitted by the wireless power transmission device to the wireless power reception device ; And adjusting at least one of the number of turns of the at least one conversion coil or the relative position of the at least one magnetostrictive resonator and the at least one conversion coil so that the magnitude of the measured power is at a maximum .

A method of matching a wireless power receiving device comprising at least one magnetostrictive resonator and at least one conversion coil in accordance with one embodiment. Measuring a magnitude of power received by the wireless power receiving apparatus from the wireless power transmission apparatus; And adjusting at least one of the number of turns of the at least one conversion coil or the relative position of the at least one magnetostrictive resonator and the at least one conversion coil so that the magnitude of the measured power is at a maximum .

FIGS. 1A and 1B are views for explaining a wireless power transmission / reception apparatus according to an embodiment.
2A and 2B are diagrams for explaining a wireless power transmission / reception apparatus according to another embodiment.
3A and 3B illustrate a wireless power transceiver according to another embodiment of the present invention.
4 is a block diagram illustrating a wireless power transceiver according to an embodiment.
5A and 5B are views for explaining a wireless power transmission apparatus and a wireless power reception apparatus according to an embodiment.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to or limited by the embodiments. In addition, the same reference numerals shown in the drawings denote the same members.

FIGS. 1A and 1B are views for explaining a wireless power transmission / reception apparatus according to an embodiment. The wireless power transceiver may include a power transmitter and a power receiver. The wireless power transmission / reception device may also refer to a wireless power transmission device or a wireless power reception device.

1A, a wireless power transceiver 110 according to one embodiment includes at least one magnetostrictive resonator 111, a soft magnetic material 112, and at least one And may include a transducing coil 113.

The at least one magnetostrictive resonator 111 may be a solid-state magnetostrictive resonator. In one embodiment, the at least one magnetostrictive resonator 111 and the at least one soft magnetic material material 112 may be in the form of a rod and may have a cylindrical dimension. In this case, at least one magnetostrictive resonator 111 may be in the form of a tube-like rod and may be composed of a magnetostrictive ferrite material. The at least one soft magnetic material material 112 may be a high-permeability ferrite rod. Also, at least one magnetostrictive resonator 111 may have the same resonant frequency.

At least one magnetostrictive resonator 111 may be excited by a magnetic field. In one embodiment, at least one magnetostrictive resonator 111 may be biased by an external permanent magnet or may have circular remanent magnetization. As at least one magnetostrictive resonator 111 is excited, at least one magnetostrictive resonator 111 can oscillate. For example, as at least one magnetostrictive resonator 111 in the form of a rod is excited, at least one magnetostrictive resonator 111 can oscillate in a torsional oscillatory manner.

At least one conversion coil 113 can convert the mechanical energy generated by the excitation of the at least one magnetostrictive resonator 111 into electrical energy. Thus, at least one conversion coil 113 can convert the vibration generated by the excitation of at least one magnetostrictive resonator 111 into electrical energy. Also, in one embodiment, at least one magnetostrictive resonator 111 can convert the electrical energy generated in the at least one magnetostrictive resonator 111 into mechanical energy.

At least one conversion coil 113 may be located around at least one magnetostrictive resonator 111 or at least one soft magnetic material material 112. At this time, at least one conversion coil 113 and at least one magnetostrictive resonator 111 may be located within a distance smaller than the length of the at least one magnetostrictive resonator 111 and at least one conversion coil 113, And at least one soft magnetic material material 112 may be located within a distance less than the length of the at least one soft magnetic material material 112.

At least one soft magnetic material material 112 may be located around the at least one magnetostrictive resonator 111. At least one magnetostrictive resonator 111 and at least one soft magnetic material material 112 may be located within a distance less than the length of the at least one magnetostrictive resonator 111 and may be aligned in a line. . In one embodiment, at least one magnetostrictive resonator 111 and at least one soft magnetic material material 112 may be positioned parallel to one another in this dimensional or three dimensional arrangement. At least one soft magnetic material material 112 may serve as a magnetic field concentrator. As at least one magnetostrictive resonator 111 and at least one soft magnetic material material 112 are in close proximity to each other, at least one soft magnetic material material 112 can concentrate the magnetic flux, A magnetic circuit may be formed. Accordingly, the magnitude of the magnetic field in the resonator can be increased, and coupling of the power transmission unit of the first wireless power transmission / reception device and the power reception unit of the second wireless power transmission / reception device (or coupling of the wireless power transmission device and the wireless power reception device The coupling can be increased, and the wireless power transmission efficiency can be increased.

Referring to FIG. 1B, a power receiving unit (or a wireless power receiving apparatus) 120 of a first wireless power transmitting / receiving apparatus according to an embodiment includes at least one magnetostrictive resonator 121, at least one soft magnetic material material 122 ), And at least one conversion coil 123. The power transmission unit (or the wireless power transmission apparatus) of the second wireless power transmission / reception apparatus according to an embodiment may include the LC resonator 130. [ The LC resonator 130 may include coil windings 131, a ferrite core 132, matching windings 133, and a capacitor 134. The coil winding 131 can form the inductance of the LC resonator 130. [ The resonance frequency of the capacitor 134 may be equal to the resonance frequency of the at least one magnetostrictive resonator 121. For example, the size of the ferrite core 132 may be 45 x 20 x 3 mm and the distance between the power receiver of the first wireless power transceiver and the power transmitter of the second wireless power transceiver The distance between the device and the wireless power transmission device) may be about 2 cm, and the length of the at least one magnetostrictive resonator 121 may be 1 cm and the diameter may be 3.5 mm. At least one conversion coil 123 may be located around the magnetostrictive resonator.

The LC resonator 130 may be excited by a generator using a matching winding 133 around the ferrite core 132. As the LC resonator 130 is excited, the LC resonator 130 can generate a magnetic field. At least one soft magnetic material material 122 may serve as a magnetic field concentrator. At least one magnetostrictive resonator 121 may be excited by a magnetic field generated from the LC resonator 130. In one embodiment, at least one magnetostrictive resonator 121 may be excited by an alternating magnetic field generated from the LC resonator 130. As at least one magnetostrictive resonator 121 is excited, at least one magnetostrictive resonator 121 can oscillate. For example, as at least one magnetostrictive resonator 121 in the form of a rod is excited, at least one magnetostrictive resonator 121 can oscillate in a torsional oscillatory manner. At least one conversion coil 123 can convert the vibration generated by the excitation of the at least one magnetostrictive resonator 121 into electrical energy.

As the at least one magnetostrictive resonator 121 and the at least one soft magnetic material material 122 are in close proximity, the magnitude of the magnetic field that excites the at least one magnetostrictive resonator 121 can be significantly increased. Accordingly, the magnitude of the magnetic field in the resonator can be increased, and coupling of the power transmission unit of the first wireless power transmission / reception device and the power reception unit of the second wireless power transmission / reception device (or coupling of the wireless power transmission device and the wireless power reception device Coupling) can be increased, and the wireless power transmission efficiency can be increased.

2A and 2B are diagrams for explaining a wireless power transmission / reception apparatus according to another embodiment.

2A, a wireless power transceiver 210 according to an embodiment includes a first magnetostrictive resonator 211, a second magnetostrictive resonator 212, and at least one transducing coil 213 .

The first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 may be solid state magnetostrictive resonators. In one embodiment, the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 may be in the form of a rod and may have a cylindrical dimension. In this case, the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 may be in the shape of a tube-like rod, and may be made of a magnetostrictive ferrite material. In addition, the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 may have the same resonance frequency. As the number of magnetostrictive resonators increases, the number of coupled magnetostrictive resonators can also be increased. Thus, the wireless power transmission efficiency can be increased.

The first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 may be excited by a magnetic field. In one embodiment, the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 may be biased by an external permanent magnet or may have a circular residual magnetization. As the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 are excited, the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 can vibrate. For example, as the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 in the form of a rod are excited, the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 are in a torsional vibration mode .

At least one conversion coil 213 can convert the vibrations generated by the excitation of the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 into electrical energy. At least one conversion coil 213 may be located around the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212. At least one conversion coil 213 and the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 are connected to the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 by a length greater than the length of the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212, Can be located within a small distance.

The first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 may be located within a distance smaller than the lengths of the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212. At this time, the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 can be aligned in a line. For example, the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 can be aligned in a line at a distance of less than 1 mm. As the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 are aligned in a line, the effect of demagnetization of the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 Can be reduced. The decrease in the effect of magnetic erasure may mean that the magnitude of the magnetic field around the first magnetostrictive resonator 211 and the second magnetostrictive resonator 212 is increased. Accordingly, the coupling of the power transmission unit of the first wireless power transmission / reception device and the power reception unit of the second wireless power transmission / reception device (or the coupling of the wireless power transmission device and the wireless power reception device) The transmission efficiency can be increased.

Referring to FIG. 2B, a power receiver 220 of a first wireless power transmitter / receiver according to an embodiment includes a first magnetostrictive resonator 221, a second magnetostrictive resonator 222, And may include at least one conversion coil 223. The power transmission unit (or the wireless power transmission apparatus) of the second wireless power transmission / reception apparatus according to an embodiment may include an LC resonator 230. [ The LC resonator 230 may include a coil winding 231, a ferrite core 232, a matching winding 233, and a capacitor 234. The coil winding 231 can form an inductance of the LC resonator 230. [ The resonance frequency of the capacitor 234 may be equal to the resonance frequency of the at least one magnetostrictive resonator 221. For example, the size of the ferrite core 232 may be 45 x 20 x 3 mm, and the distance between the power receiver of the first wireless power transceiver and the power transmitter of the second wireless power transceiver (or, The distance between the device and the wireless power transmission device) may be about 2 cm, the length of the at least one magnetostrictive resonator 221 may be 1 cm, and the diameter may be 3.5 mm. At least one conversion coil 223 may be located around the magnetostrictive resonator.

The LC resonator 230 may be excited by a generator using a matching winding 233 around the ferrite core 232. As the LC resonator 230 is excited, the LC resonator 230 can generate a magnetic field. The first magnetostrictive resonator 221 and the second magnetostrictive resonator 222 may be excited by the magnetic field generated from the LC resonator 230. [ For example, the first magnetostrictive resonator 221 and the second magnetostrictive resonator 222 may be excited by the alternating magnetic field generated from the LC resonator 230. As the first magnetostrictive resonator 221 and the second magnetostrictive resonator 222 are excited, the first magnetostrictive resonator 221 and the second magnetostrictive resonator 222 can vibrate. For example, as the first magnetostrictive resonator 221 and the second magnetostrictive resonator 222 in the form of a rod are excited, the first magnetostrictive resonator 221 and the second magnetostrictive resonator 222 are arranged in a torsional vibration mode . At least one conversion coil 223 can convert the vibrations generated by the excitation of the first magnetostrictive resonator 221 and the second magnetostrictive resonator 222 into electrical energy. As the number of magnetostrictive resonators increases, the number of coupled magnetostrictive resonators can also be increased. Thus, the wireless power transmission efficiency can be increased.

As the first magnetostrictive resonator 221 and the second magnetostrictive resonator 222 are aligned in a row, the effect of magnetic demagnetization of the first magnetostrictive resonator 221 and the second magnetostrictive resonator 222 is reduced And the magnitude of the magnetic field around the first magnetostrictive resonator 221 and the second magnetostrictive resonator 222 can be increased. As the magnitude of the magnetic field increases, the excitation of the first magnetostrictive resonator 221 and the second magnetostrictive resonator 222 may be more active. Accordingly, the coupling of the power transmission unit of the first wireless power transmission / reception device and the power reception unit of the second wireless power transmission / reception device (or the coupling of the wireless power transmission device and the wireless power reception device) The transmission efficiency can be increased.

3A and 3B illustrate a wireless power transceiver according to another embodiment of the present invention.

3A, a wireless power transceiver 310 according to an embodiment may include a first magnetostrictive resonator 311, a second magnetostrictive resonator 312, and at least one conversion coil 313 .

The first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 may be solid state magnetostrictive resonators. In one embodiment, the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 may be in the form of a rod and may have a cylindrical dimension. In this case, the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 may be in the form of a tubular rod, and may be made of a magnetostrictive ferrite material. In addition, the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 may have the same resonant frequency.

The first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 may be excited by a magnetic field. In one embodiment, the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 may be biased by an external permanent magnet or may have a circular residual magnetization. As the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 are excited, the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 can vibrate. In one embodiment, as the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 in the form of a rod are excited, the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 are excited by a torsional vibration .

At least one conversion coil 313 can convert the vibrations generated by the excitation of the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 into electrical energy. At least one conversion coil 313 may be located around the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312. At least one conversion coil 313 and the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 are connected to the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 by a length greater than the length of the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312, Can be located within a small distance.

The first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 may be located within a distance smaller than the lengths of the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312. At this time, the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 may be positioned parallel to each other in this dimensional arrangement or three-dimensional arrangement. In one embodiment, the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 are configured such that the energy exchange between the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 is such that the first magnetostriction The couplings of the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 are arranged such that the coupling of the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312 is performed at a high distance faster than the energy dissipation in the resonator 311 and the second magnetostrictive resonator 312, Or in a three-dimensional arrangement. As strong coupling is generated between the first magnetostrictive resonator 311 and the second magnetostrictive resonator 312, the radio power transmission efficiency can be increased.

Referring to FIG. 3B, a power receiving unit (or a wireless power receiving apparatus) 320 of a first wireless power transmitting / receiving apparatus according to an embodiment includes a first magnetostrictive resonator 321, a second magnetostrictive resonator 322, And may include at least one conversion coil 323. The power transmission unit (or the wireless power transmission apparatus) of the second wireless power transmission / reception apparatus according to an embodiment may include an LC resonator 330. [ The LC resonator 330 may include a coil winding 331, a ferrite core 332, a matching winding 333, and a capacitor 334. The coil winding 331 can form the inductance of the LC resonator 330. [ The resonance frequency of the capacitor 334 may be equal to the resonance frequency of the at least one magnetostrictive resonator 321. [ For example, the size of the ferrite core 332 may be 45 x 20 x 3 mm and the distance between the power receiver of the first wireless power transceiver and the power transmitter of the second wireless power transceiver The distance between the device and the wireless power transmission device) can be about 2 cm, and the length of the at least one magnetostrictive resonator 321 can be 1 cm and the diameter can be 3.5 mm. At least one conversion coil 323 may be located around the magnetostrictive resonator.

The LC resonator 330 may be excited by a generator using a matching winding 333 around the ferrite core 332. As the LC resonator 330 is excited, the LC resonator 330 can generate a magnetic field. The first magnetostrictive resonator 321 and the second magnetostrictive resonator 322 may be excited by the magnetic field generated from the LC resonator 330. [ In one embodiment, the first magnetostrictive resonator 321 and the second magnetostrictive resonator 322 may be excited by an alternating magnetic field generated from the LC resonator 330. As the first magnetostrictive resonator 321 and the second magnetostrictive resonator 322 are excited, the first magnetostrictive resonator 321 and the second magnetostrictive resonator 322 can vibrate. For example, as the first magnetostrictive resonator 321 and the second magnetostrictive resonator 322 in the form of a rod are excited, the first magnetostrictive resonator 321 and the second magnetostrictive resonator 322 are arranged in a torsional vibration mode . At least one conversion coil 323 can convert the vibrations generated by the excitation of the first magnetostrictive resonator 321 and the second magnetostrictive resonator 322 into electrical energy. As the number of magnetostrictive resonators increases, the number of coupled magnetostrictive resonators can also be increased. Thus, the wireless power transmission efficiency can be increased.

In one embodiment, the first magnetostrictive resonator 321 and the second magnetostrictive resonator 322 are configured such that the energy exchange between the first magnetostrictive resonator 321 and the second magnetostrictive resonator 322 is such that the first magnetostriction The couplings of the first magnetostrictive resonator 321 and the second magnetostrictive resonator 322 are arranged such that the coupling of the first magnetostrictive resonator 321 and the second magnetostrictive resonator 322 is faster than the energy dissipation of the resonator 321 and the second magnetostrictive resonator 322, Or in a three-dimensional arrangement. As strong coupling is generated between the first magnetostrictive resonator 321 and the second magnetostrictive resonator 322, the first magnetostrictive resonator 321 and the second magnetostrictive resonator 322 are formed as one resonator Can operate. Accordingly, the magnitude of the magnetic field in the resonator can be increased, and coupling of the power transmission unit of the first wireless power transmission / reception device and the power reception unit of the second wireless power transmission / reception device (or coupling of the wireless power transmission device and the wireless power reception device Coupling) can be increased, and the wireless power transmission efficiency can be increased.

4 is a block diagram illustrating a wireless power transceiver according to an embodiment.

Referring to FIG. 4, a wireless power transmission / reception device (hereinafter, referred to as a first wireless power transmission / reception device) 410 according to an embodiment includes a power transmission unit 420, a power reception unit 430 and a matching unit 440 . The first wireless power transceiver 410 may transmit and receive wireless power to and from a second wireless power transceiver (not shown). The power transmitting portion 420 and the power receiving portion 430 may include at least one magnetostrictive resonator, at least one soft magnetic material substance and at least one magnetostrictive resonator or at least one soft magnetic material, And at least one conversion coil located around the periphery of the material.

In the power transmission section 420 and the power reception section 430, at least one magnetostrictive resonator and at least one soft magnetic material material may be in the form of a rod and may have a cylindrical dimension. In this case, the at least one magnetostrictive resonator may be in the form of a tubular rod and may be composed of a magnetostrictive ferrite material. The at least one soft magnetic material may be a high transmittance ferrite rod. Also, at least one magnetostrictive resonator may have the same resonant frequency.

The at least one magnetostrictive resonator and the at least one soft magnetic material material can be located within a distance less than the length of the at least one magnetostrictive resonator and can be aligned in a line. In addition, at least one magnetostrictive resonator and at least one soft magnetic material material may be positioned parallel to each other in this dimensional arrangement or three-dimensional arrangement.

The at least one conversion coil and the at least one magnetostrictive resonator may be located within a distance less than the length of the at least one magnetostrictive resonator, and the at least one conversion coil and the at least one soft magnetic material material comprise at least one soft magnetic material Lt; RTI ID = 0.0 > a < / RTI >

In one embodiment, when the first wireless power transceiver 410 transmits power to a second wireless power transceiver (not shown), the at least one magnetostrictive resonator has an alternating magnetic field Lt; / RTI > The at least one magnetostrictive resonator may have a circular magnetizing current, and as the at least one magnetostrictive resonator is excited, the at least one magnetostrictive resonator may oscillate in a torsional oscillatory manner.

As the at least one magnetostrictive resonator and the at least one soft magnetic material material are in close proximity within a distance less than the length of the at least one magnetostrictive resonator, the at least one soft magnetic material material can concentrate the magnetic flux. As the magnetic flux concentrates, the excitation of the at least one magnetostrictive resonator can be more active, thereby causing at least one magnetostrictive resonator to generate more vibration. The at least one conversion coil can convert the vibration generated by the excitation of the at least one magnetostrictive resonator into electrical energy. The at least one magnetostrictive resonator may transmit the electrical energy converted by the at least one conversion coil through resonance with the resonator included in the second wireless power transmission / reception device.

In one embodiment, when the first wireless power transceiver 410 receives power from a second wireless power transceiver (not shown), the at least one magnetostrictive resonator included in the power receiver 430 may be a first wireless transceiver And may be excited by an alternating magnetic field generated by the power transceiver 410. The at least one magnetostrictive resonator may have a circular magnetizing current, and as the at least one magnetostrictive resonator is excited, the at least one magnetostrictive resonator may oscillate in a torsional oscillatory manner. The at least one conversion coil can convert the vibration generated by the excitation of the at least one magnetostrictive resonator into electrical energy. The power receiving unit 430 may transmit the converted electrical energy from at least one conversion coil to a lower end (not shown) of the first wireless power transmitting / receiving device 410.

Further, in one embodiment, the power transfer section 420 and the power receiving section 430 may include at least two magnetostrictive resonators and at least one conversion coil located around the at least two magnetostrictive resonators.

The matching unit 440 may match the first wireless power transceiver 410 and the second wireless power transceiver (not shown). The matching unit 440 adjusts the magnetic flux of the at least one magnetostrictive resonator included in the power transmitting unit 420 and the power receiving unit 430 so that the first and second wireless power transmitting / And the magnetic flux can be adjusted according to the number of turns of at least one conversion coil or the relative position of at least one magnetostrictive resonator and at least one conversion coil. Accordingly, the matching unit 440 can use the number of turns of the at least one conversion coil or the relative position of the at least one magnetostrictive resonator and the at least one conversion coil to perform the first wireless power transmission / Devices (not shown) can be matched.

In one embodiment, when the first wireless power transceiver 410 transmits power to a second wireless power transceiver (not shown), the matching unit 440 may determine that the power transceiver 420 is the second wireless power transceiver (Not shown) can be measured. The matching unit 440 includes at least one magnetostrictive resonator included in the power transmission unit 420 and at least one of the number of turns of the at least one conversion coil included in the power transmission unit 420 so that the magnitude of the measured power is maximized, The first wireless power transceiver 410 and the second wireless power transceiver (not shown) may be matched by adjusting at least one of the relative positions of the conversion coils.

In one embodiment, when the first wireless power transceiver 410 receives power from a second wireless power transceiver (not shown), the matching unit 440 may determine that the power receiver 430 is receiving power from the second wireless power receiver & (Not shown) can be measured. In the matching unit 440, the matching unit 440 may include at least the number of turns of one conversion coil included in the power receiving unit 430 or the number of turns of the at least one magnetostriction included in the power receiving unit 430, The first wireless power transceiver 410 and the second wireless power transceiver (not shown) may be matched by adjusting at least one of the relative positions of the resonator and the at least one conversion coil.

5A and 5B are views for explaining a wireless power transmission apparatus and a wireless power reception apparatus according to an embodiment.

5A, a wireless power transmission apparatus 510 may include a power transmitting unit 511 and a matching unit 512. The wireless power receiving apparatus 520 may include a power receiving unit 521 and a matching unit 522 ).

The power transmitting section 511 and the power receiving section 521 are formed of at least one magnetostrictive resonator, at least one soft magnetic material substance and at least one magnetostrictive resonator or at least one soft magnetic material element, And at least one conversion coil located around the periphery of the material. In one embodiment, the power transfer section 511 and the power receiving section 521 may include at least two magnetostrictive resonators and at least one conversion coil located around the at least two magnetostrictive resonators.

In one embodiment, at least one magnetostrictive resonator included in the power transfer portion 511 may be excited by a magnetic field generated by the current present in the conversion coil. The at least one magnetostrictive resonator may have a circular magnetizing current, and as the at least one magnetostrictive resonator is excited, the at least one magnetostrictive resonator may oscillate in a torsional oscillatory manner. The at least one conversion coil can convert the vibration generated by the excitation of the at least one magnetostrictive resonator into electrical energy. The at least one magnetostrictive resonator may transmit the converted electrical energy by at least one conversion coil through resonance with at least one magnetostrictive resonator included in the power receiving unit 521. [

The matching unit 512 may measure the magnitude of the power transmitted from the power transmitting unit 511 to the second wireless power transmitting / receiving unit 520. The matching unit 512 includes at least one magnetostrictive resonator included in the power transmitting unit 511 and at least one magnetostrictive resonator included in the power transmitting unit 511 and at least one magnetostrictive resonator included in the power transmitting unit 511, The first wireless power transceiver 510 and the second wireless power transceiver 520 may be matched to each other by adjusting at least one of the relative positions of the conversion coils of the first wireless power transceiver 510 and the second wireless power transceiver 520. [

In one embodiment, at least one magnetostrictive resonator included in the power receiver 521 may be excited by an alternating magnetic field generated by a magnetostrictive resonator included in the power transmitter 511. At least one magnetostrictive resonator included in the power receiving portion 521 may have a circular magnetizing current, and as the at least one magnetostrictive resonator is excited, the at least one magnetostrictive resonator may vibrate in a torsional vibration manner. The at least one conversion coil can convert the vibration generated by the excitation of the at least one magnetostrictive resonator into electrical energy. The power receiving unit 521 may transmit the converted electrical energy from at least one conversion coil to a lower end (not shown) of the second wireless power transmitting / receiving unit 520.

The matching unit 522 can measure the magnitude of the power received by the power receiving unit 521 from the first wireless power receiving apparatus (not shown). The matching unit 522 may be configured such that the matching unit 522 includes at least one of the number of turns of the conversion coil included in the power receiving unit 521 or the number of turns of the at least one magnetostriction included in the power receiving unit 521, The first wireless power transceiver 410 and the second wireless power transceiver (not shown) may be matched by adjusting at least one of the relative positions of the resonator and the at least one conversion coil.

FIG. 5B shows the wireless power transmission apparatus and the wireless power reception apparatus of FIG. 5A in more detail.

5B, the wireless power transmission apparatus 550 includes a variable SMPS (Variable Switching Mode Power Supply) 551, a power amplifier 552, a matching unit 554, a transmission control unit 555 And a communication unit 556. [

The variable SMPS 551 switches the AC voltage in the frequency band of several tens Hz output from the power supply to generate a direct current (DC) voltage. The variable SMPS 551 may output a constant level DC voltage or adjust the output level of the DC voltage under the control of a transmission control unit (Tx Control Logic) 555.

The variable SMPS 551 is controlled by the power amplifier 552 according to the output power level of the power amplifier 552 so that the Class-E type power amplifier 552 can always operate in a high- To maintain maximum efficiency at all output levels.

If a commercial SMPS commonly used in place of the variable SMPS 551 is used, a further variable DC-DC converter should be used. The commercial SMPS and the variable DC-DC converter are designed to supply the supply voltage according to the output power level of the power amplifier 552 so that the Class-E type power amplifier 552 can always operate in a high efficiency saturation region. So as to maintain maximum efficiency at all output levels.

The power detector 557 detects the output current and voltage of the variable SMPS 551 and transmits information on the detected current and voltage to the transmission control unit 555. The power detector 557 may also detect the input current and voltage of the power amplifier 552. [

The power amplifier 552 can generate power by converting a DC voltage of a certain level into an AC voltage by a switching pulse signal of several MHz to several tens MHz. The power amplifier 552 converts the DC voltage supplied to the power amplifier 552 to an AC voltage using the reference resonance frequency F _Ref , Power or charging power can be generated.

The power amplifier 552 may not be used when a large power corresponding to several kilowatts (KW) to several tens of kilowatts is transmitted using a resonant frequency of several tens KHz to several hundreds KHz. Power may be transferred from the variable SMPS 551 or the large power supply to the power transfer unit 553 instead. In this case, an inverter may be used instead of the power amplifier 552. [ The inverter can convert the DC power supplied from the large power source to the AC power. The inverter can convert the power by converting a DC voltage of a certain level into an AC voltage by a switching pulse signal of several tens of KHz to several hundreds of KHz. For example, the inverter can convert a DC voltage of a certain level into an AC voltage using a resonance frequency of several tens of KHz to several hundreds of KHz of the source resonator.

Here, the communication power means a small power of 0.1 to 1 mWatt, and the charging power means a large power of several milliwatts (mW) to several tens of kilowatts (KW) consumed in the device load of the wireless power receiving device 560 . In this specification, the term "charging" can be used to mean powering a unit or an element charging electric power. The term "charging" may also be used to mean powering a unit or element that consumes power. Here, a unit or an element may include, for example, a battery, a display, a sound output circuit, a main processor, and various sensors.

In the present specification, the term "reference resonance frequency" is used to mean a resonance frequency that the wireless power transmission apparatus 550 basically uses. The "tracking frequency" is used to mean a resonance frequency adjusted according to a preset method.

The transmission control section 555 detects reflected waves for the "communication power" or the "charging power" and detects a mismatching between the power receiving section 561 and the power transmitting section 553 based on the detected reflected wave do. The transmission control unit 555 can detect a mismatch by detecting the envelope of the reflected wave or the amount of power of the reflected wave.

The matching unit 554 can measure the magnitude of the power that the power transmitting unit 553 transmits to the wireless power receiving apparatus 560. [ The matching unit 554 includes at least one magnetostrictive resonator included in the power transmission unit 553 and at least one of the number of turns of the at least one conversion coil included in the power transmission unit 553 so that the magnitude of the measured power is maximized, The wireless power transmission apparatus 550 and the wireless power receiving apparatus 560 may be matched with each other by adjusting at least one of the relative positions of the conversion coils.

The transmission control unit 555 calculates a voltage standing wave ratio (VSWR) based on the level of the output voltage of the power transmission unit 553 or the power amplifier 552 and the voltage level of the reflected wave, It can be determined that the mismatching has been detected if the ratio is greater than the predetermined value.

If the voltage standing wave ratio (VSWR) is greater than a preset value, the transmission control unit 555 calculates the power transmission efficiency for each of the N tracking frequencies, and if the power transmission efficiency among the N tracking frequencies is the best The frequency F _Best can be determined, and the reference resonance frequency F _Ref can be adjusted to the F _Best .

Also, the transmission control section 555 can adjust the frequency of the switching pulse signal. The frequency of the switching pulse signal can be determined under the control of the transmission control section 555. [ The transmission control unit 555 can generate a modulation signal for transmission to the wireless power receiving apparatus 560 by controlling the power amplifier 552. [ The communication unit 556 can transmit various data 570 to the wireless power receiving apparatus 560 through in-band communication. Further, the transmission control section 555 can detect the reflected wave and demodulate the signal received from the wireless power receiving apparatus 560 through the envelope of the reflected wave.

The transmission control unit 555 may generate a modulation signal for performing in-band communication through various methods. The transmission control section 555 can generate a modulation signal by turning on / off the switching pulse signal. Further, the transmission control section 555 can perform delta-sigma modulation to generate a modulated signal. The transmission control unit 555 can generate a pulse width modulation signal having a constant envelope.

The transmission control unit 555 controls the transmission power of the wireless power receiving apparatus 560 in consideration of the temperature change of the wireless power transmission apparatus 550, the battery state of the wireless power reception apparatus 560, the change in the received power amount, To determine the initial wireless power to transmit to the device 560.

The wireless power transmission apparatus 550 may further include a temperature measurement sensor (not shown) for sensing a temperature change. Information on the battery state of the wireless power receiving apparatus 560, the change in the received power amount, or the temperature change of the wireless power receiving apparatus 560 can be received from the wireless power receiving apparatus 560 through communication.

That is, the temperature change of the wireless power receiving apparatus 560 can be detected based on the data received from the wireless power receiving apparatus 560.

At this time, the transmission control unit 555 refers to the look-up table in which the adjustment amount of the voltage supplied to the power amplifier 552 is stored in accordance with the temperature change of the wireless power transmission apparatus 550, The voltage supplied to the power amplifier 552 can be adjusted according to the change. For example, when the temperature of the wireless power transmission apparatus 550 rises, the transmission control unit 555 can lower the voltage supplied to the power amplifier 552. [

Meanwhile, the communication unit 556 may perform out-band communication using a communication channel. The communication unit 556 may include a communication module such as Zigbee or Bluetooth. The communication unit 556 may transmit the data 570 and the wireless power receiving apparatus 560 through out-band communication.

The power transmission unit 553 transfers the electromagnetic energy to the power reception unit 561. The power transmission portion 553 is disposed around at least one magnetostrictive resonator, at least one soft magnetic material substance and at least one magnetostrictive resonator or at least one soft magnetic material substance located in the periphery of the at least one magnetostrictive resonator And may include at least one conversion coil. In one embodiment, the power transfer portion 553 may include at least two magnetostrictive resonators and at least one conversion coil located around the at least two magnetostrictive resonators.

In the power transfer part 553, at least one magnetostrictive resonator and at least one soft magnetic material may be in the form of a rod and may have a cylindrical dimension. In this case, the at least one magnetostrictive resonator may be in the form of a tubular rod and may be composed of a magnetostrictive ferrite material. The at least one soft magnetic material may be a high transmittance ferrite rod. Also, at least one magnetostrictive resonator may have the same resonant frequency. The at least one magnetostrictive resonator and the at least one soft magnetic material material can be located within a distance less than the length of the at least one magnetostrictive resonator and can be aligned in a line. In addition, at least one magnetostrictive resonator and at least one soft magnetic material material may be positioned parallel to each other in this dimensional arrangement or three-dimensional arrangement. The at least one conversion coil and the at least one magnetostrictive resonator may be located within a distance less than the length of the at least one magnetostrictive resonator, and the at least one conversion coil and the at least one soft magnetic material material comprise at least one soft magnetic material Lt; RTI ID = 0.0 > a < / RTI >

In one embodiment, at least one magnetostrictive resonator included in the power transfer portion 553 may be excited by a magnetic field generated by the current present in the conversion coil. The at least one magnetostrictive resonator may have a circular magnetizing current, and as the at least one magnetostrictive resonator is excited, the at least one magnetostrictive resonator may oscillate in a torsional oscillatory manner. The at least one conversion coil can convert the vibration generated by the excitation of the at least one magnetostrictive resonator into electrical energy. The at least one magnetostrictive resonator may transmit the converted electrical energy by the at least one conversion coil through resonance with at least one magnetostrictive resonator included in the power receiving portion 561. [

The wireless power receiving apparatus 560 may include a matching unit 562, a rectifier 563, a DC-DC converter 564, a communication unit 565, and a reception control unit (Rx Control Logic) 566.

The power receiving unit 561 receives electromagnetic energy from the power transmitting unit 553. In addition, the power receiver 561 may receive various data 570 from the wireless power transmission device 550 via in-band communication.

The power receiving section 561 includes at least one magnetostrictive resonator, at least one soft magnetic material material located in the periphery of the at least one magnetostrictive resonator, and at least one magnetostrictive resonator, One conversion coil may be included. In one embodiment, the power receiver 561 may include at least two magnetostrictive resonators and at least one conversion coil located around the at least two magnetostrictive resonators.

The at least one magnetostrictive resonator may be excited by an alternating magnetic field generated by the power transfer portion 553. The at least one magnetostrictive resonator may have a circular magnetizing current, and as the at least one magnetostrictive resonator is excited, the at least one magnetostrictive resonator may oscillate in a torsional oscillatory manner. The at least one conversion coil can convert the vibration generated by the excitation of the at least one magnetostrictive resonator into electrical energy.

The matching unit 562 may match the wireless power transmission apparatus 550 and the wireless power reception apparatus 560. The matching unit 562 may match the wireless power transmission apparatus 550 and the wireless power receiving apparatus 560 by adjusting the magnetic flux of the at least one magnetostrictive resonator included in the power receiving unit 561, Can be adjusted according to the number of turns of at least one conversion coil or the relative position of at least one conversion coil and at least one magnetostrictive resonator. Accordingly, the matching unit 562 can determine the number of turns of at least one conversion coil included in the power receiving unit 561 or at least one magnetostrictive resonator included in the power receiving unit 561 At least one of the relative positions of the at least one conversion coil may be adjusted to match the wireless power transmission device 550 and the wireless power reception device 560.

The rectifier 563 rectifies the AC voltage, thereby generating a DC voltage. The rectifier 563 can rectify the received AC voltage to the power receiving unit 561. [

The DC-DC converter 564 adjusts the level of the DC voltage output from the rectifier 563 to the capacity required in the load. For example, the DC-DC converter 564 may adjust the level of the DC voltage output from the rectifier 563 to 3 to 10 Volts.

The power detector 568 can detect the voltage of the input terminal 567 of the DC-DC converter 564 and the current and voltage of the output terminal. The voltage of the detected input terminal 567 can be used to calculate the transmission efficiency of the power delivered from the source. The detected output current and voltage may be used to calculate the power to which the Rx Control Logic 555 is transferred to the Load. The transmission control unit 555 of the wireless power transmission apparatus 550 can determine the power to be transmitted from the wireless power transmission apparatus 550 considering the power required for load and the load .

When the power of the output terminal calculated through the communication unit 565 is transmitted to the wireless power transmission apparatus 550, the wireless power transmission apparatus 550 can calculate the power to be transmitted.

The communication unit 565 can perform in-band communication in which data is transmitted and received using the resonance frequency. At this time, the reception control unit 566 may detect a signal between the power receiving unit 561 and the rectifier 563 and demodulate the received signal, or may detect the output signal of the rectifier 563 and demodulate the received signal. That is, the reception control unit 566 can demodulate the received message through the in-band communication. The reception control section 566 can modulate the signal to be transmitted to the wireless power transmission apparatus 550 by adjusting the impedance of the power reception section 561 through the matching section 562. [ The reception control section 566 may increase the impedance of the power receiving section 561 to cause the transmission control section 555 of the wireless power transmission apparatus 550 to detect the reflected wave. The transmission control section 555 of the wireless power transmission apparatus 550 detects a first value (e.g., binary number "0") or a second value (e.g., a binary number "1 & can do.

Meanwhile, the communication unit 565 may perform out-band communication using a communication channel. The communication unit 565 may include a communication module such as Zigbee or Bluetooth. The communication unit 565 can transmit and receive data 570 to and from the wireless power transmission apparatus 550 through out-band communication.

The method according to an embodiment may be implemented in the form of a program command that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions to be recorded on the medium may be those specially designed and configured for the embodiments or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the embodiments, and vice versa.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. For example, it is to be understood that the techniques described may be performed in a different order than the described methods, and / or that components of the described systems, structures, devices, circuits, Lt; / RTI > or equivalents, even if it is replaced or replaced.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

Claims (22)

At least one magnetostrictive resonator excited by a magnetic field;
At least one soft magnetic material positioned around the at least one magnetostrictive resonator; And
At least one magnetostrictive resonator or at least one transducing coil located around the at least one soft magnetic material element,
/ RTI >
Wherein the at least one conversion coil comprises:
Transforming the mechanical energy generated by excitation of said at least one magnetostrictive resonator into electrical energy,
Wireless power transceiver.
The method according to claim 1,
Wherein the at least one magnetostrictive resonator and the at least one soft magnetic material material are arranged such that,
In rod form,
Wireless power transceiver.
The method according to claim 1,
Wherein the at least one magnetostrictive resonator and the at least one soft magnetic material material are arranged such that,
Wherein said at least one magnetostrictive resonator is located within a distance less than the length of said at least one magnetostrictive resonator,
Wireless power transceiver.
The method according to claim 1,
The at least one conversion coil and the at least one magnetostrictive resonator,
A resonator located within a distance less than the length of said at least one magnetostrictive resonator,
Said at least one conversion coil and said at least one soft magnetic material material,
The soft magnetic material being located within a distance less than the length of the at least one soft magnetic material material,
Wireless power transceiver.
The method according to claim 1,
Wherein the at least one soft magnetic material material comprises:
A high-permeability ferrite rod,
Wireless power transceiver.
The method according to claim 1,
Wherein the at least one magnetostrictive resonator and the at least one soft magnetic material material are arranged such that,
Aligned in a line,
Wireless power transceiver.
3. The method of claim 2,
Wherein the at least one magnetostrictive resonator comprises:
A tube-shaped rod-shaped, magnetostrictive ferrite material,
Wireless power transceiver.
3. The method of claim 2,
Wherein the at least one magnetostrictive resonator comprises:
Having a circular remanent magnetization and vibrating in a torsional vibrational mode as excited by the magnetic field,
Wireless power transceiver.
6. The method of claim 5,
Wherein the at least one magnetostrictive resonator and the at least one soft magnetic material material are arranged such that,
With a cylindrical dimension,
Wireless power transceiver.
The method according to claim 1,
Wherein the at least one magnetostrictive resonator and the at least one soft magnetic material material are arranged such that,
Dimensional array or a three-dimensional array.
Wireless power transceiver.
The method according to claim 1,
Wherein the at least one magnetostrictive resonator comprises:
Having the same resonance frequency,
Wireless power transceiver.
At least two magnetostrictive resonators excited by a magnetic field; And
At least one conversion coil located around the at least two magnetostrictive resonators
/ RTI >
Wherein the at least one conversion coil comprises:
Transforming the mechanical energy generated by excitation of said at least two magnetostrictive resonators into electrical energy,
Wireless power transceiver.
13. The method of claim 12,
Wherein the at least two magnetostrictive resonators comprise:
In the form of a load,
Wireless power transceiver.
13. The method of claim 12,
Said at least one conversion coil and said at least two magnetostrictive resonators,
Wherein said at least two magnetostrictive resonators are located within a distance less than the length of said at least two magnetostrictive resonators,
Wireless power transceiver.
14. The method of claim 13,
Wherein the at least two magnetostrictive resonators comprise:
Having a circular residual magnetization and vibrating in a torsional vibration manner as excited by the magnetic field,
Wireless power transceiver.
13. The method of claim 12,
Wherein the at least two magnetostrictive resonators comprise:
Within a distance less than the length of said at least two magnetostrictive resonators,
Wireless power transceiver.
13. The method of claim 12,
Wherein the at least two magnetostrictive resonators comprise:
Parallel to each other, within a distance smaller than the length of the at least two magnetostrictive resonators,
Wireless power transceiver.
13. The method of claim 12,
Wherein the at least two magnetostrictive resonators comprise:
Dimensional array or a three-dimensional array.
Wireless power transceiver.
13. The method of claim 12,
Wherein the at least two magnetostrictive resonators comprise:
Having the same resonance frequency,
Wireless power transceiver.
A method of matching a wireless power transmission device comprising at least one magnetostrictive resonator and at least one conversion coil,
Measuring a magnitude of power transmitted by the wireless power transmission apparatus to the wireless power reception apparatus; And
Adjusting at least one of the number of turns of the at least one conversion coil or the relative position of the at least one magnetostrictive resonator and the at least one conversion coil so that the magnitude of the measured power is maximized
/ RTI >
A method for matching a wireless power transmission device.
A matching method of a wireless power receiving apparatus including at least one magnetostrictive resonator and at least one conversion coil,
Measuring a magnitude of power received by the wireless power receiving apparatus from the wireless power transmission apparatus; And
Adjusting at least one of the number of turns of the at least one conversion coil or the relative position of the at least one magnetostrictive resonator and the at least one conversion coil so that the magnitude of the measured power is maximized
/ RTI >
A method for matching a wireless power receiving apparatus.
A computer-readable recording medium having recorded thereon a program for performing the method of any of claims 20 and 21.

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