A vehicle system includes a motor, a first device connected to the motor and configured to supply the motor with power, a fuel cell connected to the first device and configured to charge the first device, a second device connected to the fuel cell, a first converter interposed between the fuel cell and the first device and configured to adjust a voltage from one of the fuel cell or the first device and to supply power to the other, a second converter interposed between the fuel cell and the second device and configured to adjust a voltage from the second device and to apply the adjusted voltage to the fuel cell, and a third converter interposed between the first device and the second device and configured to adjust a voltage from one of the first device or the second device and to supply power to the other.

A vehicle performs notification about an open/closed state of a lid member covering an interface for supplying driving energy. The vehicle includes a notification portion that performs notification when the lid member is in the open state and a connection detecting portion that detects a connection state of a driving energy supply device to the interface. In the vehicle, the notification portion suspends notification when the driving energy supply device is connected to the interface during the open state of the lid member.

The operator control unit (10) for a device is provided with an operator control element (14) which has a touch-sensitive operator control surface (16). The operator control element (14) is, for the purpose of being automatically returned to its inoperative position after being deflected out of said inoperative position, elastically mounted in said inoperative position. The mechanical excitation of the operator control element (14) out of its inoperative position for the purpose of tactile feedback in response to operation of the operator control element (14) is performed by means of an actuator (24). A sensor (26) identifies the movement of the operator control element (14) and/or an acceleration and/or force acting on the operator control element (14). When a movement of the operator control element (14) and/or an acceleration and/or force acting on the operator control element (14) are/is identified without sensing contact

A charging cable unit for a charging column of an electric filling station has a cooling unit and a charging cable which is preferably provided with cable shoes. The coding unit includes a heat exchanger with first connections and second connections. The charging cable has a secondary coolant circuit that is fluidically connected to the second connections. The cooling unit is designed to cool the secondary coolant circuit if the first connections are fluidically connected to a common primary coolant circuit of the electric filling station. Also described is a mounting method using such a charging cable unit.

A charging inlet 10 disclosed by this specification includes a plate 50 provided with a connector insertion hole 51, and an inlet body 20 having a connector fitting portion 22 to be inserted into the connector insertion hole 51, the inlet body 20 being fixed to the plate 50. The connector fitting portion 22 includes a peripheral wall 25 having a cylindrical shape and a lock portion 34 provided on an outer peripheral surface of the peripheral wall 25. The connector insertion hole 51 includes a peripheral wall accommodation space 56 having the peripheral wall 25 accommodated therein and a lock portion accommodation space 57 having the lock portion 34 accommodated therein. The peripheral wall 25 is provided with drainage ports 39 allowing communication between the lock portion accommodation space 57 and the inside of the peripheral wall 25.

System, methods, and other embodiments described herein relate to adjusting a trip fare according to in-vehicle charging provided by a passenger. In one embodiment, a method includes, in response to initiating a trip in the vehicle for a passenger, accumulating the trip fare as a function of traveling a route to fulfill the trip. The method includes metering one or more charging devices to identify a metered charge produced by the passenger operating the one or more charging devices during the trip. The method includes computing a fare offset according to at least the metered charge to identify an amount by which the trip fare is to be discounted. The method includes adjusting the trip fare according to the fare offset to account for an electric charge provided to the vehicle during the trip.

A charging device including a first interface, by which the first connection between the charging device and a local network can be established; a second interface by which a second connection between the motor vehicle and the charging device can be established so that when the first connection is established, a data exchange between the local network and the motor vehicle is possible; at least one further interface by which a further connection between a further participant and the charging device can be established so that when the first connection is established, a data exchange between the local network and the further participant is possible; and a control device that is designed to request a predefined certificate from the vehicle and to establish the further connection without requesting and authenticating the predefined certificate.

A method for controlling a mobile shop includes: determining a selling situation of a plurality of items using information about an inventory status of the plurality of items and information about a well-selling time of the plurality of items; setting a charging schedule for a battery (secondary battery) based on the selling situation; and causing the mobile shop to move to EVSE (charging facility) according to the charging schedule.

The application relates to direct current, DC, charging cable including two DC conductors configured for transmitting electrical energy between an electrical vehicle and a charging device, at least a signal line having a first signal line end and a second, opposite signal line end and a control device, the first signal line end is connected at a first connection point to one of the DC conductors, and the control device is configured for measuring a voltage difference between the second signal line end and a second connection point of the one of the DC conductors distant to the first connection point for determining a temperature of the DC charging cable.

A vehicle system of the present invention includes: a motor configured to drive a vehicle; a high voltage storage device connected to the motor and configured to supply the motor with power; a fuel cell connected to the high voltage storage device and configured to charge the high voltage storage device; and a low voltage storage device connected to the fuel cell. The vehicle system includes: a bidirectional first voltage converter interposed between the fuel cell and the high voltage storage device, and configured to adjust a voltage at either of the fuel cell or the high voltage storage device and to supply power to the other; and a second voltage converter interposed between the fuel cell and the low voltage storage device, and configured to adjust a voltage at the low voltage storage device and to apply the adjusted voltage to the fuel cell. The vehicle system is characterized in that the vehicle system includes a bidirectional third voltage converter interposed between the high voltage storage device and the low voltage storage device, and configured to adjust a voltage at either of the high voltage storage device or the low voltage storage device and to supply power to the other.