A transport vehicle for containers, in particular a floor-bound and driverless heavy-load transport vehicle for ISO containers, has a platform for receiving at least one container to be transported, with the platform being delimited by guide elements for guiding a container when being deposited on the platform, and includes a drive unit and a battery module for supplying electric energy to the drive unit. The battery module has a support frame and a battery, with there being at least one air conditioner device arranged in the support frame together with the battery.

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 energy store tank assembly includes a tank adapted for mounting to a frame of a tractor-trailer vehicle by a mounting bracket. The mounting bracket is coupled to the frame, and the mounting bracket extends around, and in contact with, a circumference of the tank to secure the tank to the frame. The energy store tank assembly further includes an energy store disposed within the tank, the energy store configured to supply electrical power to the tractor-trailer vehicle in a first mode of operation and further configured to receive energy from the tractor-trailer vehicle in a second mode of operation. In some embodiments, the tank includes an electrical interface through which the energy store supplies the electrical power to the tractor-trailer vehicle in the first mode of operation and through which the energy store receives energy from the tractor-trailer vehicle in the second mode of operation

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 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 total task vehicle (TTV) may operate indoors to move a variety of different types of materials and accomplish a variety of different types of tasks, using tools and accessories powered by/connected to the TTV. One or more high power density (HD) battery packs may provide both 240V DC to 380V DC and 120V AC power to propel the TTV and also to function as a generator for tools and accessories attached to the TTV. A high torque/high speed convertible drive system may allow the TTV to operate in a ride-on mode, a walk-behind mode, providing for flexibility and adaptability in use of the TTV.

This application is directed to an apparatus for providing electrical charge to a vehicle. The apparatus comprises a driven mass, a generator, a charger, a hardware controller, and a communication circuit. The driven mass rotates in response to a kinetic energy of the vehicle and is coupled to a shaft such that rotation of the driven mass causes the shaft to rotate. The driven mass exists in one of (1) an extended position and (2) a retracted position. The generator generates an electrical output based on a mechanical input coupled to the shaft such that rotation of the shaft causes the mechanical input to rotate. The charger is electrically coupled to the generator and: receives the electrical output, generates a charge output based on the electrical output, and conveys the charge output to the vehicle. The controller controls whether the driven mass is in the extended position or the retracted position in response to a signal received from the communication circuit.

The disclosure is related to an electric wheel, adapted to a wheel shaft. The electric wheel includes a wheel body, a battery holder, and at least one battery module. The wheel body has a wheel hub configured to be rotatably disposed on the wheel shaft. The battery holder includes a base and at least one first electrical connector connected to each other. The base is configured to be connected to the wheel shaft and disposed side by side to the wheel hub. The base has an outer surface facing away from the wheel shaft. The at least one battery module includes at least one battery storage and at least one second electrical connector. The at least one battery storage has an inner surface in contact with the outer surface of the base. The at least one second electrical connector is detachably mounted on the at least one first electrical connector.

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.

An embodiment is directed to a module-to-module power connector configured to form connections between battery modules installed in a battery housing of an energy storage system. The module-to-module power connector includes electrical interfaces and busbar(s) configured to form one or more electrical connections terminals of adjacent battery modules. The busbar(s) is flexibly configured to permit a defined range of movement of the electrical interfaces during insertion of the respective battery modules into respective battery module compartments. The module-to-module power connector may further be arranged inside in a tunnel space, whereby holes are defined in a battery module mounting area housing the battery modules that open into the tunnel space.