A wireless vehicle charging system is provided herein. The charging system includes a charging station having a power source and a charging station interface operably coupled to a primary coil assembly. The primary coil assembly includes a primary coil therein for generating a magnetic field. An illumination system is disposed within the primary coil assembly and includes a passive illumination system and an active illumination system. A first photoluminescent structure is disposed within the passive illumination system and is configured to luminesce in response to excitation by an incident light. A second photoluminescent structure is disposed within the active illumination system and is configured to luminesce in response to excitation by a light source. A vehicle having a secondary coil assembly thereon is operably coupled with a rectifier and is configured to transmit electrical current from the secondary coil assembly to a battery.

An embodiment of the invention relates to a charging device for charging an at least partially electrically operated vehicle. The charging device is formed with at least one electrical component and a switching device. The at least one electrical component and the switching device are arranged in the charging device in such a way that when the charging device is connected to a vehicle a circuit is produced for assisting the discharging of at least one capacitor provided on the vehicle side, the capacitor being openable or closable via the switching device.

A power reception apparatus includes a secondary coil which receives power in a non-contact state from a power transmission apparatus having a primary coil, while being disposed opposite to the power transmission apparatus, a housing which accommodates the secondary coil to form a space between the secondary coil and the housing, an insulating fluid filled in the space, a measurement unit which measures efficiency of a non-contact power transmission between the primary coil and the secondary coil, and a detection unit which detects damage made to the housing based on a change in the efficiency during the non-contact power transmission.

An adapter having a CHAdeMO socket on its input side for receiving a charging station connector of a CHAdeMO charging station, a CCS connector on its output side for connection to an electric vehicle, and an electronic circuit logic which embeds signal states entering via the CHAdeMO socket into a CAN message and to provide them as an output signal.

An onboard battery includes predetermined members such as battery modules, and a housing case. An internal space of the housing case is partitioned by a partition plate into an upper space and a lower space in which the predetermined members are disposed, and the battery modules are disposed below the partition plate. The housing case has a bottom surface on which the battery modules are disposed, a front surface that has a front-side tightening part, and a rear surface that has a rear-side tightening part. The partition plate has a partition base that partitions the internal space of the housing case into the upper space and the lower space, a front-side fixation target part that is continuous with a front end of the partition base, and a rear-side fixation target part that is continuous with a rear end of the partition base.

A battery system includes a housing, a battery array inside the housing, a first wiring path that bypasses the battery array, and a second wiring path electrically connected to the battery array. The battery system is adapted to charge a battery pack of an electrified vehicle using AC power, DC power, or both.

A method includes controlling an electrified vehicle by modifying a state of charge (SOC) window associated with an energy storage device of the electrified vehicle in response to a reverse driving event or a trailer towing event.

A power supply device includes: an electric storage unit; a connection unit connected to the electric storage unit; a housing which houses the electric storage unit; a power receiving unit which receives AC power in a noncontact manner; a rectifier which converts the AC power into DC power and outputs the DC power; an AC lead wire which connects the power receiving unit and the rectifier; and a DC lead wire which connects the rectifier and the connection unit. The power receiving unit is connected to the housing via a heat conduction unit, an opening is provided on a surface facing the power receiving unit in the housing, any one of the AC lead wire, the DC lead wire and the rectifier is disposed to pass through the opening, and the housing has a heat capacity larger than that of the power receiving unit.

The power reception apparatus includes a secondary coil which receives power in a non-contact state from a power transmission apparatus having a primary coil, while facing the power transmission apparatus, a housing which houses the secondary coil to form a space between the secondary coil and the housing, a fluid filled in the space, a sensor which is disposed in the space and detects a change in the a liquid level height of the fluid, and a detection unit which detects a breakage of the housing, based on a the change in the liquid level height detected by the sensor.

Techniques for wirelessly transferring energy to a vehicle are disclosed. An example method for wirelessly transferring energy to a vehicle according to the disclosure includes detecting a ripple frequency on a transmitter coil circuit, such that the ripple frequency is associated with a vehicle switch mode controller frequency of a switch mode controller in the vehicle, and providing an electrical current to a coil in the transmitter coil circuit based at least in part on the ripple frequency.