Implementations described herein provide systems and methods for wireless charging. In one implementation, a base has a planar surface. One or more posts extend from the planar surface of the base to form a core. Each of the one or more posts is formed from a plurality of nanocrystalline sheets. The plurality of nanocrystalline sheets of each of the one or more posts is oriented in planes perpendicular to the planar surface of the base. One or more coils are wound around each of the one or more posts to form coil windings.

A storage apparatus that stores objects includes a housing; a fixed part disposed in the housing and fixed in a position against the housing; a rotating part connected to the fixed part through a rotating shaft extending in the vertical direction and rotates relative to the fixed part as a center of the rotating shaft; and a rotating shaft driving part that rotates the rotating shaft; wherein the fixed part includes a power-transmission unit that transmits electric power in noncontact state; and the rotating part includes a rotating shelf on which objects are disposed; a power drive device disposed to rotate integrally with the rotating shelf and driven by electric power; and a power-receiving unit that supplies the electric power transmitted from the power-transmission unit to the power drive device.

A storage apparatus that stores objects includes a housing; a fixed part disposed in the housing and fixed in a position against the housing; a rotating part connected to the fixed part through a rotating shaft extending in the vertical direction and rotates relative to the fixed part as a center of the rotating shaft; and a rotating shaft driving part that rotates the rotating shaft; wherein the fixed part includes a power-transmission unit that transmits electric power in noncontact state; and the rotating part includes a rotating shelf on which objects are disposed; a power drive device disposed to rotate integrally with the rotating shelf and driven by electric power; and a power-receiving unit that supplies the electric power transmitted from the power-transmission unit to the power drive device.

A wireless power-receiving device with near field communication function includes a communication antenna on a flat surface for near field communication, an interface circuit connected to the antenna and allowing a signal in the near field communication to pass, a wireless communication IC that is connected to the interface circuit and processes the signal, a receiving coil on the flat surface, a resonant capacitor included, with the receiving coil, in a receiving resonant circuit, and a rectifying/smoothing circuit connected to the receiving resonant circuit. The receiving resonant circuit resonates at a frequency for the near field communication, a resonance current flowing through the receiving resonant circuit causes a current to flow through the coil, a main flux is generated near the coil, and a magnetic path of the main flux is isolated from a magnetic path of a magnetic flux for the near field communication interlinking with the antenna.

A wireless power-receiving device with near field communication function includes a communication antenna on a flat surface for near field communication, an interface circuit connected to the antenna and allowing a signal in the near field communication to pass, a wireless communication IC that is connected to the interface circuit and processes the signal, a receiving coil on the flat surface, a resonant capacitor included, with the receiving coil, in a receiving resonant circuit, and a rectifying/smoothing circuit connected to the receiving resonant circuit. The receiving resonant circuit resonates at a frequency for the near field communication, a resonance current flowing through the receiving resonant circuit causes a current to flow through the coil, a main flux is generated near the coil, and a magnetic path of the main flux is isolated from a magnetic path of a magnetic flux for the near field communication interlinking with the antenna.

A wireless charging apparatus according to an embodiment can improve heat dissipation and charging efficiency by adjusting the surface area of a magnetic pad. Therefore, the wireless charging apparatus can be effectively used for a transportation means, such as an electric vehicle, which requires high-capacity power transmission between a transmitter and a receiver.

A wireless charging apparatus according to an embodiment can improve heat dissipation and charging efficiency by adjusting the surface area of a magnetic pad. Therefore, the wireless charging apparatus can be effectively used for a transportation means, such as an electric vehicle, which requires high-capacity power transmission between a transmitter and a receiver.

The position information transmission device is provided at one of a ground side apparatus and a moving object performing non-contact power transmission by magnetic field resonance coupling with the ground side apparatus, and includes an alternating current power generation circuit for generating alternating current power, an alternating current magnetic field generation circuit for generating an alternating current magnetic field as a position signal when the alternating current power is applied; and a power inflow suppression part for keeping induced electromotive force due to an alternating current magnetic field generated from a power transmission side resonance circuit for the non-contact power transmission from flowing to the alternating current power generation circuit.

In a wireless charging system, a transmitter coil of a wireless charger device and a receiver coil of a portable electronic device can operate at either of two different operating frequencies. The low frequency can be in a range from about 300 kHz to about 400 kHz, and the high frequency can be in a range from about 1 MHz to about 2 MHz. To provide efficient charging at both frequencies, the transmitter and receiver coils can be formed from a compound, or multi-stranded, wire.

In a wireless charging system, a transmitter coil of a wireless charger device and a receiver coil of a portable electronic device can operate at either of two different operating frequencies. The low frequency can be in a range from about 300 kHz to about 400 kHz, and the high frequency can be in a range from about 1 MHz to about 2 MHz. To provide efficient charging at both frequencies, the transmitter and receiver coils can be formed from a compound, or multi-stranded, wire.