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.

An apparatus including a first electrical connector; and a second electrical connector. The first and second electrical connectors have magnets to provide a magnetic holding force with each other and provide alignment of the electrical connectors to hold the second electrical connector against the first electrical connector at a predetermined position. Magnetic poles of the magnets are configured to limit orientation of the second electrical connector on the first electrical connector. The second electrical connector includes two power contacts and an interruption detector contact, where the power contacts are movably mounted on the second housing and configured to disconnect from electrical contacts of the first electrical connector, when the second electrical connector is being disconnected from the first electrical connector, only after the interruption detector contact of the second plurality of electrical contacts disconnects from an electrical contact of the first electrical connector.

A system for ground power supply of aircraft includes at least one mobile transformer unit having a first vehicle chassis and a voltage transformer mounted on the first vehicle chassis; at least two energy stores which can be alternately connected to an input of the voltage transformer in order to supply the voltage transformer with electric energy; and a supply cable for ground power supply of one of the aircraft. The supply cable is configured to be connected to an output of the voltage transformer. Each of the at least two energy stores is part of one of at least two mobile storage units each including a second vehicle chassis. The first vehicle chassis of the transformer unit and each of the second vehicle chassis of the at least two mobile storage units are moveable on the ground independently on each other.

A system for ground power supply of aircraft includes at least one mobile transformer unit having a first vehicle chassis and a voltage transformer mounted on the first vehicle chassis; at least two energy stores which can be alternately connected to an input of the voltage transformer in order to supply the voltage transformer with electric energy; and a supply cable for ground power supply of one of the aircraft. The supply cable is configured to be connected to an output of the voltage transformer. Each of the at least two energy stores is part of one of at least two mobile storage units each including a second vehicle chassis. The first vehicle chassis of the transformer unit and each of the second vehicle chassis of the at least two mobile storage units are moveable on the ground independently on each other.

Charge adaptors may be provided as part of a bidirectional energy transfer system for charging multiple vehicles from a single power source. An exemplary charge adaptor may enable intelligent charging of multiple vehicles from the power source through various configurations (e.g., daisy-chain, multiplex, etc.) and strategies (e.g. sequential, parallel, staged, etc.). A microcontroller of the charge adaptor may serve as the primary controller of energy flow through a bidirectional energy transfer system, with other connected devices such as the charge source, vehicles, and other charge adaptors configured to function as periphery control devices. The charge adaptor may implement an AC coupled design in which a common voltage bus is utilized to splice energy to other charge adaptors for enabling bidirectional energy transfers.

Charge adaptors may be provided as part of a bidirectional energy transfer system for charging multiple vehicles from a single power source. An exemplary charge adaptor may enable intelligent charging of multiple vehicles from the power source through various configurations (e.g., daisy-chain, multiplex, etc.) and strategies (e.g. sequential, parallel, staged, etc.). A microcontroller of the charge adaptor may serve as the primary controller of energy flow through a bidirectional energy transfer system, with other connected devices such as the charge source, vehicles, and other charge adaptors configured to function as periphery control devices. The charge adaptor may implement an AC coupled design in which a common voltage bus is utilized to splice energy to other charge adaptors for enabling bidirectional energy transfers.

The present invention presents a method providing an additional service during electric vehicle charging by (a) the electric vehicle charger (200) detecting connection with an electric vehicle (100) via a charging cable; (b) the electric vehicle charger (200) exchanging charging messages through a charging port in a PLC modem, when the connection is detected in step (a); and (c) the electric vehicle charger (200) providing an additional service for the electric vehicle once the charging begins, and therefore, providing additional services such as software updates, vehicle contents updates requested by a driver during the charging of the electric vehicle, and thus providing convenience for the car owners without visiting car diagnostic service center.

The present invention presents a method providing an additional service during electric vehicle charging by (a) the electric vehicle charger (200) detecting connection with an electric vehicle (100) via a charging cable; (b) the electric vehicle charger (200) exchanging charging messages through a charging port in a PLC modem, when the connection is detected in step (a); and (c) the electric vehicle charger (200) providing an additional service for the electric vehicle once the charging begins, and therefore, providing additional services such as software updates, vehicle contents updates requested by a driver during the charging of the electric vehicle, and thus providing convenience for the car owners without visiting car diagnostic service center.

A deployable charging point assembly for a vehicle includes a connecting part for connecting to a supply of electrical power separate from the vehicle. The connecting part is mountable on the vehicle, such that the connecting part is movable relative to a body of the vehicle between a first position and a second position. The charging point assembly is configured to establish an electrical connection between the supply of electrical power and an electrical system of the vehicle when the connecting part is in one or more predetermined positions between the first and second positions.

A deployable charging point assembly for a vehicle includes a connecting part for connecting to a supply of electrical power separate from the vehicle. The connecting part is mountable on the vehicle, such that the connecting part is movable relative to a body of the vehicle between a first position and a second position. The charging point assembly is configured to establish an electrical connection between the supply of electrical power and an electrical system of the vehicle when the connecting part is in one or more predetermined positions between the first and second positions.