Disclosed is a system for recharging a selected power source wirelessly, such as through a power transmission. The power source may be positioned within a subject and be charged wirelessly through the subject, such as tissue of the subject. A thermal transfer system is provided to transfer or transport thermal energy from a first position to a second position, such as away from the subject.

The disclosure is the only product of its kind that utilizes a Bluetooth connectivity to generate and transfer power from power outlets into other devices to support their performance. The disclosure is uniquely designed in two different sizes, one to activate TV's or gaming consoles and a slightly larger pod for larger electronic gadgets. Both charging pods utilize an advanced power aggregation technology and are highly portable and simple to use to guarantee practicality and versatility. A wireless transceiver housed in the wall plug or pod transmits an electrical power across a carrier frequency and a frequency converter housed in the wall plug and configured to convert the carrier frequency to a predetermined AC (alternating current) frequency at a predetermined AC voltage, Multiple electrical milliwatt power sources as disclosed each wirelessly transmit to a receiver for an aggregated wattage power reception.

The disclosure is the only product of its kind that utilizes a Bluetooth connectivity to generate and transfer power from power outlets into other devices to support their performance. The disclosure is uniquely designed in two different sizes, one to activate TV's or gaming consoles and a slightly larger pod for larger electronic gadgets. Both charging pods utilize an advanced power aggregation technology and are highly portable and simple to use to guarantee practicality and versatility. A wireless transceiver housed in the wall plug or pod transmits an electrical power across a carrier frequency and a frequency converter housed in the wall plug and configured to convert the carrier frequency to a predetermined AC (alternating current) frequency at a predetermined AC voltage, Multiple electrical milliwatt power sources as disclosed each wirelessly transmit to a receiver for an aggregated wattage power reception.

A wireless power transfer system in which the driver and control circuitry are located within the electromagnetic field of the power transmission antenna, e.g., a charging coil. The power transfer system may be contained in a flexible housing, which change shape using one or more hinges, be formed of a conformable material and so on. Changes in the relative location of the antenna and the circuitry may cause interference in the circuitry and loading of the antenna, which in turn may impact the electromagnetic field output by the antenna. The wireless power system may include sensors that provide an indication of an amount of deformation of the system. The driver circuitry of this disclosure may receive an indication of the relative location of the circuitry to the antenna and compensate for changes in the output electromagnetic field caused by changes in the relative location.

A wireless power transfer system in which the driver and control circuitry are located within the electromagnetic field of the power transmission antenna, e.g., a charging coil. The power transfer system may be contained in a flexible housing, which change shape using one or more hinges, be formed of a conformable material and so on. Changes in the relative location of the antenna and the circuitry may cause interference in the circuitry and loading of the antenna, which in turn may impact the electromagnetic field output by the antenna. The wireless power system may include sensors that provide an indication of an amount of deformation of the system. The driver circuitry of this disclosure may receive an indication of the relative location of the circuitry to the antenna and compensate for changes in the output electromagnetic field caused by changes in the relative location.

A vehicle interior panel assembly includes an in-vehicle support substrate and a stowage tray for a mobile device. The stowage tray includes a reception surface for the mobile device, and one or more sliders configured to attach the stowage tray to the support substrate. The one or more sliders are further configured to tilt the reception surface with respect to a sowed position for the stowage tray in the support substrate. This structure for a stowage tray helps improve within vehicle integration and support more flexible useability.

An electronic device is disclosed. The electronic device discloses a plurality of wireless charging antennas, a plurality of shielding partition layers, at least some of the plurality of shielding partition layers disposed between the plurality of wireless charging antennas, a plurality of external device-receiving grooves formed through spaces defined between pairs of the shielding partition layers, and a processor electrically coupled to the plurality of wireless charging antennas. The processor is configured to: determine whether at least one external device is inserted into at least one of the plurality of external device-receiving grooves, and when the at least one external device is inserted into the at least one of the plurality of external device-receiving grooves, wirelessly transmit power through at least one wireless charging antenna corresponding to the at least one of the plurality of external device-receiving grooves into which the at least one external device is inserted.

An electronic device is disclosed. The electronic device discloses a plurality of wireless charging antennas, a plurality of shielding partition layers, at least some of the plurality of shielding partition layers disposed between the plurality of wireless charging antennas, a plurality of external device-receiving grooves formed through spaces defined between pairs of the shielding partition layers, and a processor electrically coupled to the plurality of wireless charging antennas. The processor is configured to: determine whether at least one external device is inserted into at least one of the plurality of external device-receiving grooves, and when the at least one external device is inserted into the at least one of the plurality of external device-receiving grooves, wirelessly transmit power through at least one wireless charging antenna corresponding to the at least one of the plurality of external device-receiving grooves into which the at least one external device is inserted.

An intermediate circuit is equipped with a first terminal connection, which includes a neutral conductor connection, and with a first and a second intermediate circuit capacitor and a diode circuit. The intermediate circuit has configuration switches which in a first state connect the intermediate circuit capacitors to one another in series and in a second state connect the intermediate circuit capacitors to one another in parallel. The configuration switches are each designed as changeover switches, which bypass the diode circuit in the first state, wherein the neutral conductor connection is connected to the diode circuit. A vehicle-based charging circuit, which includes the intermediate circuit and a rectifier circuit, is also described.

An intermediate circuit is equipped with a first terminal connection, which includes a neutral conductor connection, and with a first and a second intermediate circuit capacitor and a diode circuit. The intermediate circuit has configuration switches which in a first state connect the intermediate circuit capacitors to one another in series and in a second state connect the intermediate circuit capacitors to one another in parallel. The configuration switches are each designed as changeover switches, which bypass the diode circuit in the first state, wherein the neutral conductor connection is connected to the diode circuit. A vehicle-based charging circuit, which includes the intermediate circuit and a rectifier circuit, is also described.