Foldable electrical vehicles and related charging infrastructure are described. The foldable electrical vehicle generally includes three structural members (front and rear wheel-bearing structural members and a seat-bearing structural member) that are pivotally interconnected along their lengths such that they may be pivoted between a closed position wherein the three structural members are disposed roughly parallel to each other in a compact folded configuration, and an open riding configuration wherein an angular relation is formed between the structural members.

A mechanical stabilization system for a battery assembly is disclosed. The system includes an actuator and a stabilizer that are configured to work in concert. The actuator and stabilizer are disposed in a housing of the battery assembly. The system may be implemented by depression of the actuator disposed in the housing, which causes the stabilizer to retract a support post into the housing. The depression can occur during a docking operation of the battery assembly with a lift mechanism for an electric vehicle. When the actuator is released, the support post automatically reverts to its previous, deployed state. The support post is configured to maintain the battery assembly in a stable configuration when the battery assembly is separated from the electric vehicle.

An electric vehicle includes a drive unit fitted to a rear axle of the electric vehicle to transmit drive power generated by a motor to rear wheels of the electric vehicle, an auxiliary electric device group including a plurality of auxiliary electric devices disposed in a cab area which is disposed under a cab of the electric vehicle and between side rails which constitute a ladder frame of the electric vehicle, a battery pack disposed between the drive unit and the auxiliary electric device group and between the side rails, a power distribution device disposed on an auxiliary electric device group side of the battery pack and between the side rails to distribute power from the battery pack to the auxiliary electric devices, and a drive power supply device disposed on a drive unit side of the battery pack to supply power from the battery pack to the motor.

An arrangement structure for devices in a power unit chamber of a vehicle includes an air cleaner disposed in the power unit chamber; a battery disposed adjacently to and behind the air cleaner in the vehicle; and a cover disposed above the battery and the air cleaner. The front end of the cover is located further forward of the vehicle than the rear end of the air cleaner, and the minimum dimension of a space between the cover and the air cleaner is greater than the height of the battery.

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.

A method and system for swapping batteries in an electric vehicle is disclosed. The method includes dismounting a first battery assembly, moving to a second battery assembly and mounting the second battery assembly onto the vehicle. Mounting and dismounting are accomplished by an onboard mounting and dismounting system. The method can be used in a zero infrastructure environment such as an underground mine since mounting and dismounting are accomplished by components on the vehicle itself. An auxiliary battery pack powers the vehicle during between dismounting a battery pack and mounting another battery pack.

An alignment and locking system for a battery assembly is disclosed. The system may be located onboard of an electric vehicle powered by a battery pack disposed in the battery assembly. The system includes a set of receiving members fixed to the chassis. The battery assembly includes a cage with mounting bars. When the mounting bars are received in the receiving members they may be locked into place against the chassis. The system can also include a set of v-blocks that engage vertically oriented bars in the cage to help with horizontal alignment of the battery assembly.

A mounting and dismounting system for a battery assembly is disclosed. The system may be located onboard of an electric vehicle powered by a battery pack disposed in the battery assembly. The system includes a pair of four-bar linkages that can be used to raise and lower the battery assembly. Each four-bar linkage includes a pair of hooks with different vertical positions. The hooks are positioned to grasp horizontal mounting bars that are disposed on the battery assembly. Using vertically displaced hooks ensures the battery can be raised and lowered without rocking.

A zero emissions electrically powered haul truck is disclosed. The haul truck has a 40 metric ton hauling capacity and a form factor that allows the truck to travel through underground mines. The truck also includes a primary battery assembly that is externally mounted along the front and sides of the truck.

Pickup trucks with an internal combustion engine (ICE), all electric, hybrid, plug in hybrid, must walk on loading flat bed, to load or unload, two stationary side walls, one-fold down tail gate, two taillights one on each side at the rear next to the fold down tail gate. With two full doors, with two full doors and with two smaller rear doors, or four full doors. It takes less compressed clean air to drive the DC alternators or DC generators from the compressed clean air engine. Also, the vehicle does drive 100% electric. A combination 100% electric and 100% compressed clean air system. No other vehicle has this kind of system.