In certain aspects, an enclosure for a wireless power transfer pad is disclosed. The enclosure includes a cover shell configured to be positioned over a portion of the wireless power transfer pad configured to face a wireless power receiver when wirelessly transferring power, wherein at least a portion of the cover shell is made of a heat resistant material.

A non-contact power supply system supplies power in a non-contact manner between a power transmission coil of a power supply device and a power reception coil of a vehicle. The power supply device side communication unit transmits identification information of the power supply device to the vehicle. The generation unit generates a power pattern list by allocating each piece of the identification information that is received by the vehicle side communication unit to several power patterns based on a prescribed rule. The vehicle side communication unit transmits the power pattern list to the power supply device. The controller causes power to be outputted from the power transmission coil to the power reception coil according to a power pattern which corresponds to the identification information. The determination unit determines establishment of a paired communication based on a comparison the detected power pattern and a power pattern.

A power reception-side coil is mounted on the bottom surface of a vehicle body and contactlessly receives power transmitted from a power feeding-side coil disposed on the ground. The power reception-side coil is of a solenoid type such that an electric wire is wound with the vehicle longitudinal direction as a coil axis. A shield member that is a plate-shaped magnetic shield is disposed between the bottom surface of the vehicle body and the power reception-side coil. The shield member has a forward-inclined surface serving as a first wall part protruding downward of the vehicle, the forward-inclined surface being raised and provided at the vehicle front side in a direction of the coil axis with respect to the power reception-side coil.

An inductive charging unit for a vehicle includes a trough-shaped base support having a base surface and the base surface has laterally enclosing side walls where the base surface and the side walls form a trough. The charging unit further includes a top surface opposite the base surface and a primary coil for inductive coupling to a secondary coil associated with the vehicle, where the primary coil is disposed in the trough. A filling material is disposed in the trough and surrounds the primary coil so as to fix the primary coil mechanically.

An inductive charging unit for a vehicle includes a trough-shaped base support having a base surface and the base surface has laterally enclosing side walls where the base surface and the side walls form a trough. The charging unit further includes a top surface opposite the base surface and a primary coil for inductive coupling to a secondary coil associated with the vehicle, where the primary coil is disposed in the trough. A filling material is disposed in the trough and surrounds the primary coil so as to fix the primary coil mechanically.

An electrified vehicle includes a wireless charger that wirelessly receives power from an external source, cameras, LEDs, a speaker, and at least one controller programmed individually or in combination to, when the wireless charger is receiving power from the external source, process images from at least one of the cameras and operate the LEDs and the speaker based on detection of an object within the images. The controller may change the color of the LEDs and/or sound emitted by the speaker in response to whether the object is detected within a first zone farther from the vehicle or a second zone nearer the vehicle. The LEDs and cameras may be positioned on external side mirrors, front, rear, and/or underbody portions of the vehicle. The speaker may be external to the vehicle cabin and provide an audible signal when operating the vehicle in electric mode at low speeds.

An electrified vehicle includes a wireless charger that wirelessly receives power from an external source, cameras, LEDs, a speaker, and at least one controller programmed individually or in combination to, when the wireless charger is receiving power from the external source, process images from at least one of the cameras and operate the LEDs and the speaker based on detection of an object within the images. The controller may change the color of the LEDs and/or sound emitted by the speaker in response to whether the object is detected within a first zone farther from the vehicle or a second zone nearer the vehicle. The LEDs and cameras may be positioned on external side mirrors, front, rear, and/or underbody portions of the vehicle. The speaker may be external to the vehicle cabin and provide an audible signal when operating the vehicle in electric mode at low speeds.

The present invention provides a system tar wireless power transmission, wherein the system is a system for wireless power transmission detecting a foreign object, including a power transmitting coil for transmitting AC power, a power receiving coil for receiving the AC power transmitted from the power transmitting coil wherein the power receiving coil is spaced apart from the power transmitting coil, and a detection circuit for detecting a foreign object located between the power transmitting coil and the power receiving coil wherein a first resistor and a first detection coil connected in series, and a second resistor and a second detection coil connected in series are connected in parallel, and wherein at least one of the first detection coil and the second detection coil is disposed between the power transmitting coil and the power receiving coil.

The present invention provides a system tar wireless power transmission, wherein the system is a system for wireless power transmission detecting a foreign object, including a power transmitting coil for transmitting AC power, a power receiving coil for receiving the AC power transmitted from the power transmitting coil wherein the power receiving coil is spaced apart from the power transmitting coil, and a detection circuit for detecting a foreign object located between the power transmitting coil and the power receiving coil wherein a first resistor and a first detection coil connected in series, and a second resistor and a second detection coil connected in series are connected in parallel, and wherein at least one of the first detection coil and the second detection coil is disposed between the power transmitting coil and the power receiving coil.

The invention relates to a device for the transferring energy by induction, for a vehicle, between at least one emitter coil and at least one receiver coil of the vehicle, said at least one receiver coil being arranged at a distance from said at least one emitter coil, a field concentrator being arranged between the at least one emitter coil and the at least one receiver coil.