A battery lockout device is provided. The battery lockout device may include a safety plug body adapted to engage a power port of the battery. The battery lockout device may further include a rotating member operatively connected to the safety plug body, the rotating member engaging a battery lip or battery lip housing. The rotating member, in a first rotated position, can be locked in the first rotated position preventing access to the power port of the battery and preventing removal of the safety body plug from the battery. To effectuate locking the rotating member in the first rotated position, a keyed lock can be used to maintain the first rotated position of the rotating member relative to the safety plug body and the battery/battery housing lip. In this way, no energy from the battery may be discharged until removal/disengagement of the battery lockout device.

A battery lockout device is provided. The battery lockout device may include a safety plug body adapted to engage a power port of the battery. The battery lockout device may further include a rotating member operatively connected to the safety plug body, the rotating member engaging a battery lip or battery lip housing. The rotating member, in a first rotated position, can be locked in the first rotated position preventing access to the power port of the battery and preventing removal of the safety body plug from the battery. To effectuate locking the rotating member in the first rotated position, a keyed lock can be used to maintain the first rotated position of the rotating member relative to the safety plug body and the battery/battery housing lip. In this way, no energy from the battery may be discharged until removal/disengagement of the battery lockout device.

The invention concerns a charger for aeronautical maintenance equipment, the charger comprising at least one so-called “high-frequency” input electrical connector comprising a plurality of power supply pins capable of receiving a three-phase AC voltage delivered by an external power supply source at a frequency of 400 Hz, and two detection pins, a so-called “high-frequency” charging module, connected to the at least one high-frequency input electrical connector, intended to be connected to a power storage module of the aeronautical maintenance equipment, and capable of converting the AC voltage received at the plurality of power supply pins of the high-frequency input electrical connector into a DC voltage for charging the storage module, and a control module capable of generating a detection voltage between the detection pins of the high-frequency input electrical connector allowing the external power supply source, when it detects the detection voltage, to authorize the supply of the AC voltage to the plurality of power supply pins of the high-frequency input electrical connector.

An electric vehicle includes a wheel, an electric motor to drive the wheel, a battery to supply electric power to the electric motor, the battery including battery cells and a battery casing to house the battery cells, an onboard charger to charge the battery, the onboard charger being opposed to and spaced apart from an outer surface of the battery casing so that an air flow path exists between the onboard charger and the outer surface of the battery casing, and a cooling fan to generate a flow of air passing through the air flow path between the onboard charger and the battery casing.

A straddled electric vehicle includes a wheel, an electric motor to drive the wheel, a battery to supply electric power to the electric motor, a DC charging port to receive a DC current output from a first external power source, and an AC charging port to receive an AC current output from a second external power source. A first distance between the DC charging port and the battery is smaller than a second distance between the AC charging port and the battery.

An electric vehicle charging method includes at a user terminal, transmitting a location information of the user terminal to a management sever; at the management sever, determining at least one usable charging device corresponding to the location information; at the management sever, transmitting information for at least one determined charging device to the user terminal; at the user terminal, choosing at least one charging device among the at least one determined charging device; at the user terminal, transmitting a preemption request information for preemption at least one chosen charging device to the management server; at the management sever, locking at least one charging device corresponding to the preemption request information by transmitting a preemption order signal; at the management sever, transmitting information for a user of the user terminal to locked charging device; and unlocking the charging device corresponding to inputting a authentication information for authentication of the user.

An electric vehicle charging method includes at a user terminal, transmitting a location information of the user terminal to a management sever; at the management sever, determining at least one usable charging device corresponding to the location information; at the management sever, transmitting information for at least one determined charging device to the user terminal; at the user terminal, choosing at least one charging device among the at least one determined charging device; at the user terminal, transmitting a preemption request information for preemption at least one chosen charging device to the management server; at the management sever, locking at least one charging device corresponding to the preemption request information by transmitting a preemption order signal; at the management sever, transmitting information for a user of the user terminal to locked charging device; and unlocking the charging device corresponding to inputting a authentication information for authentication of the user.

An electrical plug connector includes a connector housing receiving an electrical terminal. The connector housing has an outer cooling gas connection cooling an electrical plug-in connection of the plug connector with a mating plug connector. A cooling gas is brought into the plug connector by the outer cooling gas connection through a cooling gas channel of the connector housing.

An electrical plug connector includes a connector housing receiving an electrical terminal. The connector housing has an outer cooling gas connection cooling an electrical plug-in connection of the plug connector with a mating plug connector. A cooling gas is brought into the plug connector by the outer cooling gas connection through a cooling gas channel of the connector housing.

A charging system for an electric vehicle that receives electric power from external charging equipment to charge a battery includes an inlet including a plurality of ports. The inlet is connectable to the external charging equipment. A charging management part includes a control pilot (CP) terminal for receiving a charging signal indicating information related to a charging power source of the external charging equipment through the inlet. The CP terminal includes a CP plus terminal connected to a CP port among the plurality of ports of the inlet. The CP plus terminal is configured to receive the charging signal. A CP minus terminal is directly connected to a ground port among the plurality of ports of the inlet. The CP minus terminal is configured to receive a ground potential of the external charging equipment.