Various personal mobility vehicles, such as scooters, are disclosed. The scooter can include at least one battery and motor for powering at least one driven wheel. The vehicle can include a gear assembly to convert a torque produced by the motor to a different torque to a driven shaft to power the at least one driven wheel. The battery can be removable.

An embodiment is directed to a battery module mounting area of an energy storage system. The battery module mounting area includes a first set of battery module compartments arranged along a first longitudinal side of the battery module mounting area, and a second set of battery module compartments arranged along a second longitudinal side of the battery module mounting area. Each battery module compartment in the first and second sets of battery module compartments includes an insertion-side through which a battery module is configured to be inserted into the battery module compartment and/or removed from the battery module compartment. The insertion-side of each battery module compartment in the first and second sets of battery module compartments is configured to be closed via an insertion-side cover to form a battery housing with a closed compartment profile that is characterized by each battery module compartment being sealed from at least one other battery module compartment in the battery housing.

The invention relates to an electrically powered industrial truck, in particular a narrow aisle forklift truck, comprising a battery box for housing a battery block, which box is open on at least one side for removing the battery block in the width direction of the vehicle and comprises on its top face a strut extending substantially in the longitudinal direction of the vehicle, and at least one locking device for the battery block housed in a battery box, wherein the at least one locking device comprises a mount associated with the strut, a pivot shaft, which extends above the battery box in the width direction of the industrial truck and is pivotally held by the mount, and a pivot lever, which is carried by the pivot shaft and is pivotable between a locking position and a releasing position, wherein the pivot lever is designed, when in its locking position, to support the battery block in the width direction of the vehicle and, when in its releasing position, to release the battery block in the width direction of the vehicle.

A vehicle floor structure is provided including: a vehicle interior opening formation section provided inside a vehicle cabin, and demarcating a vehicle interior opening that opens into the vehicle cabin; a vehicle exterior opening formation section provided further toward a vehicle lower side than a floor inside the vehicle cabin, and demarcating a vehicle exterior opening that opens toward a vehicle exterior; a storage section provided at the vehicle lower side of the floor, and demarcating a storage space that connects the vehicle interior opening and the vehicle exterior opening together; and a pull-out receptacle disposed inside the storage section at a position corresponding to the vehicle interior opening, and capable of moving from inside the storage section to the vehicle exterior through the vehicle exterior opening.

An electric work vehicle includes a carrier provided separately from a vehicle body for mounting/dismounting a battery, a carrier storage section provided in the vehicle body for attaching the carrier to the vehicle body, and an attachment mechanism for attaching/detaching the carrier to/from the carrier storage section.

In an embodiment, a clamping bar holder component configured to be secured to an endplate of a battery module includes a plurality of clamping bar holders configured to hold a respective plurality of clamping bars and to facilitate transitions of each of the plurality of clamping bars between a parked state and an unparked state. In the parked state, each clamping bar is secured by a respective clamping bar holder inside of a respective clearance threshold so as to permit the battery module to be inserted into a battery module compartment and/or to be removed from the battery module compartment. In the unparked state, each clamping bar extends out of the clamping bar holder past the clearance threshold so as to block removal of the battery module from the battery module compartment.

A two-way distribution, charging, and vending system permits a subscriber to exchange one or more partially or completely discharged portable electric energy storage devices for a comparable number of charged portable electric energy storage devices. The two-way distribution, charging, and vending system includes a number of charging modules, each with a dedicated power converter, communicably coupled to at least one two-way distribution system controller and to a power distribution grid. Upon receipt of a discharged portable electric energy storage device, the at least one two-way distribution system controller validates a manufacturer identifier and a subscriber identifier stored in a nontransitory storage media carried by the discharged portable electric energy storage device. Responsive to a successful authentication and validation, the at least one two-way distribution system controller dispenses a charged portable electric energy storage device to the subscriber.

A system for installation of traction batteries for a vehicle having a chassis comprising at least one load-carrying frame member. A front bracket member and a rear bracket member are adapted to be secured to and project from the frame member of the vehicle for receiving a traction battery between the front bracket member and the rear bracket member. The system also comprises a first and a second slider adapted to be connected to a front and a rear side, respectively, of a traction battery. The sliders are adapted to be mated with the bracket members subsequently to the sliders having been connected to the traction battery, thereby enabling the traction battery by means of the connected sliders to be received by the bracket members and be moved towards the frame member of the vehicle.

A vehicle that is an electric vehicle, includes a battery, a vehicle body, a fastening member, and a cleansing unit. The vehicle body includes a mounting portion. The mounting portion is configured to mount the battery. The fastening member fastens the battery to the mounting portion. The cleansing unit cleanses the fastening member.

In an embodiment, a battery module arrangement is configured for deployment with respect to a battery module compartment within a battery module mounting area of an energy storage system. The battery module arrangement includes a battery module configured to be inserted into and/or removed from an interior space of the battery module compartment via an insertion-side of the battery module compartment, and a clamp-based insertion-side cover configured to be closed over the insertion-side of the battery module compartment. The clamp-based insertion-side cover includes an endplate of the battery module, a compartment section of the battery module compartment, and a plurality of endplate-to-compartment clamping arrangements that are integrated as part of the clamp-based insertion-side cover and are configured to secure the battery module inside of the battery module compartment by clamping the endplate to the compartment section.