An EV charging control apparatus may include a controller receiving a charging approval message for an EV from a charging management server, starting a charging to the EV in response to the charging approval message, measuring and accumulating an amount of energy charged to the EV, recognizing a charging termination operation from a user of the EV or the EV, and deriving charging information based on the amount of energy charged in response to the charging termination operation, and a short-range wireless communication module establishing a connection with a short-range wireless communication module mounted on the EV, and transmitting the charging information to the EV

The present invention relates to a device for positioning a charger connector, in particular relative to a vehicle contra connector, comprising a suspension for a charging cable assembly, connected at one end to the charger connector, the suspension comprising a first suspension point, for clamping, at a point remote from the one end, the charging cable assembly in a predetermined orientation and position, which orientation and position together with the rigidity of the cable assembly and the gravity acting on the cable assembly define a preferred position and/or a preferred orientation of the one end; and a second suspension point, for engaging the charging cable assembly at the one end of the charger connector; Wherein the second suspension point comprises a manipulator for manipulating the position and/or the orientation of the charger connector relative to the fixed world, in a range around the preferred position and/or the preferred orientation of the one end of the cable assembly.

A vehicle power supply device is provided. The vehicle power supply device includes: a fixed base; a scissor-fork lifting mechanism, where the scissor-fork lifting mechanism is mounted on the fixed base; a power supply head, where the power supply head is mounted on the scissor-fork lifting mechanism and is driven by the scissor-fork lifting mechanism to ascend or descend; and a drive device, where the drive device includes a drive unit and a transmission unit configured to convert rotational movement into linear movement. The drive unit and the transmission unit are stacked along a lifting direction of the scissor-fork lifting mechanism. The drive unit is connected with the scissor-fork lifting mechanism by the transmission unit to drive the scissor-fork lifting mechanism to ascend or descend.

A charging system includes a service vehicle and a controller. The service vehicle includes a chassis, a series of tractive elements coupled to the chassis, an energy storage device, and a charging interface operatively coupled to the energy storage device. The controller is configured to identify a location of a vehicle, control the service vehicle to navigate to the location of the vehicle, and control the service vehicle to transfer energy from the energy storage device to the vehicle through the charging interface.

A system includes an automatic charging device. The automatic charging device includes a movable arm configured to connect a charging plug head in electric communication with a vehicle inlet of an electric vehicle. The system includes a current detector configured to be in electrical communication with the automatic charging device.

A system includes an automatic charging device. The automatic charging device includes a movable arm configured to connect a charging plug head in electric communication with a vehicle inlet of an electric vehicle. The system includes a current detector configured to be in electrical communication with the automatic charging device.

An electric vehicle charging station (10) comprises a pillar (12) and a casing (14) for installing underground. The casing (14) has a base (26), a side wall (24) and a top (22) defining an inner space, an opening (28) being provided in the top (22) for receiving the pillar (12). The electric vehicle charging station (10) includes a power socket (30) for connection to a power supply and for receiving a power connector of an electric vehicle. The power socket (30) is joined to the pillar (12) and situated near a top end of the pillar (12), the bottom end of the pillar (12) is received in the opening (28) of the casing and the pillar (12) is movable between a retracted position for storing the pillar (12) within the inner space of the casing (14) below ground, and an extended position for supporting the power socket (30) outside the casing (14) above ground.

An electric vehicle charging station (10) comprises a pillar (12) and a casing (14) for installing underground. The casing (14) has a base (26), a side wall (24) and a top (22) defining an inner space, an opening (28) being provided in the top (22) for receiving the pillar (12). The electric vehicle charging station (10) includes a power socket (30) for connection to a power supply and for receiving a power connector of an electric vehicle. The power socket (30) is joined to the pillar (12) and situated near a top end of the pillar (12), the bottom end of the pillar (12) is received in the opening (28) of the casing and the pillar (12) is movable between a retracted position for storing the pillar (12) within the inner space of the casing (14) below ground, and an extended position for supporting the power socket (30) outside the casing (14) above ground.

A method for orienting a power receiving coil of a vehicle relative to a power emitting coil of a wireless charging system for a vehicle. The method includes detecting a positioning of the vehicle at a charging location in which the power receiving coil detects reception of electromagnetic radiation emitted from the power emitting coil, performing a calibration sequence in which the orientation of the power receiving coil and/or the power emitting coil is varied according to a predetermined scheme, while registering the electromagnetic radiation reception of the power receiving coil, in response to the calibrations sequence, determining a desired relative orientation including relative angle between the power receiving coil and the power emitting coil for which the electromagnetic radiation reception of the power receiving coil is in a top range of the registered electromagnetic radiation reception.

A charging apparatus for charging a battery of an electrically operable vehicle includes a plug element, a base element, and adjusting facility. The plug element is connectable to a corresponding, vehicle-side plug element of the motor vehicle and via which electrical energy is transferrable to the motor vehicle so as to charge the battery. The base element is connected to a current source and provides electrical energy from the current source for the plug element. Via the adjusting facility the plug element is movable relative to the base element in order to connect the plug element to the vehicle-side plug element, and via which an electrical connection is provided between the base element and the plug element. The adjusting facility has an overload protection via which the base element is electrically separated from the plug element in the event of a predetermined mechanical maximal load being exceeded.