A vehicular removable battery removably mountable in an electric vehicle includes a time acquirer configured to acquire a current time, a time period storage storing a time period in which electric power is supplied, and an electric power supply controller configured to control the supply of the electric power stored in an electric power storage to the electric vehicle. After the electric power supply controller detects that an activation instruction of the electric vehicle has been issued, the electric power supply controller is configured to enable the supply of the stored electric power to the electric vehicle in a case where the acquired current time is included in the stored time period. The electric power supply controller is configured to prohibit the supply of the electric power to the electric vehicle in a case where the acquired current time is not included in the stored time period.

An electric vehicle includes a power storage device configured to feed electric power to a motor for traveling, a front compartment provided in front of a cabin of the electric vehicle in the electric vehicle, a power supplying port that is provided in the front compartment and outputs electric power from the power storage device and configured such that a power supplying cable is connected with the power supplying port, an external power supplying device configured to feed electric power of the power storage device to an outside of the electric vehicle from the power supplying port, and a fuel cell stack disposed inside the front compartment.

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.

A connection in a power aggregation system for distributed electric resources is located by establishing, by way of a computer network, a communication between a mobile electric resource and a network-connected device, the mobile electric resource including one or more processors including a processor to control power flow, obtaining, with the one or more processors, a unique identifier associated with the network-connected device, transmitting, with the one or more processors, information regarding the mobile electric resource to a remote server, determining, with the one or more processors or the remote server, a location of the mobile electric resource from the unique identifier, determining at least one power connection location from the determined location, and charging the mobile electric resource with the determined at least one power connection location.

A battery pack (10) supplies power to a vehicle (20), and comprises a receiver (11), a signal analyzer (12), and a discharge controller (14). The receiver (11) receives from the vehicle (20) a proper use signal generated by the vehicle (20). The signal analyzer (12) analyzes the proper use signal received by the receiver (11). The discharge controller (14) permits power supply to the vehicle (20) when it has been confirmed, as a result of analysis by the signal analyzer (12), that a proper use signal has been received from the vehicle (20).

Provided is an electric scooter with a top-swappable battery. In some embodiments, the electric scooter a frame having an opening, and a removable deck assembly disposed in the opening, the removable deck assembly comprising a deck having an upper surface and a lower surface, and a battery pack attached to the lower surface of the deck.

A direct current (DC) electric vehicle supply equipment (EVSE) that includes a secure enclosure. The secure enclosure encloses a set of one or more contactors to open and close to provide DC charge transfer with one or more electric vehicles; a conductor to electrically connect the contactors with DC input; a current sensor to measure current draw; a voltage sensing circuitry to measure voltage; and one or more circuits that receive current data from the current sensor and voltage data from the voltage sensing circuitry, the one or more circuits to perform one or more safety functions and one or more metering functions using the received current data and voltage data. The DC EVSE may also include, external to the secure enclosure, a controller that is coupled with the circuits to control the opening and closing of the set of contactors.

An electric vehicle charging connector, including a set of pins, a sensor, and a controller. The set of pins may include a DC pin, wherein the DC pin is configured to supply DC power to a charging port, wherein the charging port comprises a locking mechanism. The sensor can detect power flow from the pins to the charging port. The controller is communicatively connected to the sensor and configured to receive a signal from the sensor and send a locking signal to a locking mechanism. The locking mechanism comprises an engaged state wherein the charging connector is mechanically coupled to the charging port and a disengaged state wherein the charging connector is mechanically uncoupled form the charging port, wherein the locking mechanism is configured to receive a locking signal from the controller of the charging connector and enter the engaged state.

A network of collection, charging and distribution machines collect, charge and distribute portable electrical energy storage devices (e.g., batteries, supercapacitors or ultracapacitors). To charge, the machines employ electrical current from an external source, such as the electrical grid or an electrical service of an installation location. The charging and distribution machines may distribute portable electrical energy storage devices of particular performance characteristics and other attributes based on customer preferences and/or customer profiles. The charging and distribution machines may provide instructions to or otherwise program portable electrical energy storage devices stored within the charging and distribution machines to perform at various levels according to user preferences and user profiles.

It is described a rechargeable battery pack (20) for an electric or hybrid vehicle (1), comprising: at least one electric connection member (23) to a powertrain group (5) of the electric or hybrid vehicle (1); a plurality of mutually electrically connected cells (30); at least one first circuit block (40) integrated in the rechargeable battery pack (20) and comprising a receiver (41) of satellite geo-localization signals and a processing unit (42) of said signals, which is operatively connected to said receiver (41) and adapted to detect a piece of information of geographic positioning of the rechargeable battery pack (20) in a geo-referenced system.