An electromotive drive for motor vehicle applications. In particular, the electromotive drive is part of a locking device of an electric connection device for electric or hybrid motor vehicles. For this purpose, an electric motor and a multistage transmission which is arranged downstream of the electric motor are provided as drive elements for acting on an actuating element, and a drive housing which houses drive elements is also provided. The actuating element is a locking element of the locking device for example. The drive housing is equipped with inner and/or edge-side protrusions. The protrusions have direct bearing points for individual drive elements or all of the drive elements.

An electric vehicle includes: a rotary electric machine configured to generate a driving force for driving driving wheels; a driving battery storing power to drive the rotary electric machine; a converter connected to the driving battery; an auxiliary battery connected to the driving battery via the converter; and a cooling box connected to the auxiliary battery. When the driving battery has an SOC reduced to be smaller than a prescribed threshold value, the converter is stopped and power remaining in the auxiliary battery is used to drive the cooling box.

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 method for joining a drivetrain to a vehicle body, includes the steps of: transferring the drivetrain and the vehicle body into a joining position, arranging an electrical connecting element on a chassis part of the drivetrain, and joining the drivetrain to the vehicle body, wherein the drivetrain and the vehicle body are connected together at predetermined points via fasteners.

An electric vehicle (1) has a battery (2) in an underfloor arrangement. The battery (2) is arranged in a battery space (4) that is delimited by body members (5, 6, 7, 8) of a body (3). The battery space (4) also is delimited at a bottom side of the electric vehicle (1) by way of a protective plate (9). The battery (2) has a connection element (10, 11) at least on a side oriented toward one of the body members (7, 8), and the body member (7, 8) has a recess (12, 13) in which the connection element (10, 11) is arranged.

A system may be provided that may include a first battery, and an inverter coupled to the battery. The system may also include a first active filter including a first switch element, second switch element, third switch element, and fourth switch element. Each switch element may be coupled to the first battery or the inverter. The first, second, third, and fourth switch elements may be configured to increase or decrease an applied voltage or current of the first battery.

A charging station includes an alternating current (AC) electrical power input and at least one direct current (DC) electrical power module coupled to the AC electrical power input. The charging station also includes at least one station output having a vehicle DC electrical power output, a communications output, and a dispenser DC electrical power output, the dispenser DC electrical power output being configured to be coupled to at least one dispenser. The charging station further includes a communications hub including at least one communications network connection, the communications hub being configured to receive information relating to an amount of DC electrical power to be delivered to a particular dispenser coupled to the charging station. Further still, the charging station includes a master controller configured to receive the information from the communications hub relating to the amount of DC electrical power to be delivered to the particular dispenser coupled to the charging station and provide a control signal to one of the at least one DC electrical power modules, the control signal being based on the information and being configured to control the amount of DC electrical power sent through one of the at least one DC electrical power modules.

A system for charging an electric vehicle having at least one power induction coil under control of a processor wirelessly charges an electric vehicle, wherein the at least one power induction coil is positioned in proximity to a parking location; and a parking manager device manages permissions for electric vehicles to park in one or more parking locations included in a parking zone associated with the parking manager device, wherein the parking manager also manages permissions for electric vehicles to charge via wireless charging while parked in the one or more parking locations, wherein the parking manager device has a unique address and the zone, parking locations, and charging stations associated with the parking manager device have associated unique sub-addresses associated with the parking manager device unique address.

A method for controlling a charge transfer of an electric vehicle using an electric vehicle charging station, a mobile device, and a cloud server is disclosed. The method includes: receiving, at a mobile device, a message for an electric vehicle of a user from the electric vehicle charging station, wherein a user of the mobile device is associated with the electric vehicle to be charged; sending, from the mobile device, the message for the electric vehicle of the user to the cloud server, wherein the charge transfer request relayed from the mobile device includes identification information; in response to a charging control signal being authorized using identification information received from the mobile device, receiving the charging control signal from the cloud server at the mobile device to be forwarded to the electric vehicle charging station, wherein the charging control signal is configured to adjust a charging parameter at the electric vehicle charging station.

The invention concerns a system for distributing, delivering and collecting freight, with a number I of mobile freight stations, with I ≥1, each having a first interface for automatically loading freight into freight vehicles from a freight storage of the mobile freight station and for automatically unloading freight from freight vehicles into the freight storage, wherein the freight vehicles are arranged and executed for automatically loading/unloading freight via the first interface and for automatically securing/fixing freight in a storage space of the freight vehicles, the mobile freight stations each have a number ni ≤Ni, with i=1, . . . , I, of delivery robots, where Ni is the maximum number of delivery robots present in the ith freight station and ni is the number of delivery robots currently present in the ith freight station, and the I freight stations each have a loading device for automatically loading the Ni delivery robots with a respective freight from the freight storage and for automatically unloading a respective freight from the N.sub.i delivery robots into the freight storage.