Provided are a battery locking/unlocking system, and an electric vehicle battery swapping control system and a control method thereof. The battery locking/unlocking system comprises a battery swapping device used for moving a battery; a lock shaft detection unit used for generating a location signal; a lock tongue control unit used for controlling a lock tongue to fall into the lock slot or retract to the outside of the lock slot; a data exchange unit separately communicates with the battery swapping device and the lock shaft detection unit. According to the battery locking/unlocking system and locking and unlocking control methods, by providing various location detection components, the battery is accurately located and locked when being loaded into a fixing base, and then accurately located and unlocked when being removed, thereby achieving full-automatic control during swapping of the battery and improving the swapping speed and success rate of the battery.

Provided are a battery locking/unlocking system, and an electric vehicle battery swapping control system and a control method thereof. The battery locking/unlocking system comprises a battery swapping device used for moving a battery; a lock shaft detection unit used for generating a location signal; a lock tongue control unit used for controlling a lock tongue to fall into the lock slot or retract to the outside of the lock slot; a data exchange unit separately communicates with the battery swapping device and the lock shaft detection unit. According to the battery locking/unlocking system and locking and unlocking control methods, by providing various location detection components, the battery is accurately located and locked when being loaded into a fixing base, and then accurately located and unlocked when being removed, thereby achieving full-automatic control during swapping of the battery and improving the swapping speed and success rate of the battery.

A battery replacement system is configured to move a spare battery to an automatic guided vehicle. The battery replacement system includes a charging stand and a carrier. The charging stand includes a base and a plurality of supporting seat. The supporting seats are pivotably disposed on the base and configured to support the spare battery. The carrier includes a frame and a clamping component. The frame is located aside the charging stand. The clamping component is movably disposed on the frame and configured to replace a vehicle battery on the automatic guided vehicle with the spare battery.

A battery replacement system is configured to move a spare battery to an automatic guided vehicle. The battery replacement system includes a charging stand and a carrier. The charging stand includes a base and a plurality of supporting seat. The supporting seats are pivotably disposed on the base and configured to support the spare battery. The carrier includes a frame and a clamping component. The frame is located aside the charging stand. The clamping component is movably disposed on the frame and configured to replace a vehicle battery on the automatic guided vehicle with the spare battery.

A system and method for selecting a battery (e.g., a battery selector) is disclosed. The example battery selector includes a plurality of battery factors, a plurality of electrical load factors, a plurality of cycling or crank data, and an output. The output includes a battery selection based on the plurality of battery factors, plurality of vehicle loads, and the plurality of cycling or crank data.

A system and method for selecting a battery (e.g., a battery selector) is disclosed. The example battery selector includes a plurality of battery factors, a plurality of electrical load factors, a plurality of cycling or crank data, and an output. The output includes a battery selection based on the plurality of battery factors, plurality of vehicle loads, and the plurality of cycling or crank data.

A robot with rechargeable and interchangeable batteries. The robot includes a body coupled to a wheel assembly, the wheel assembly including a plurality of wheels and a drive mechanism arranged to move the body along a first set of parallel rails extending in a first direction and a second set of parallel rails extending in a second direction perpendicular to the first direction. The body has a chassis defining a first battery compartment and a second battery compartments with a first battery module disposed within the first battery compartment. When the chassis engages with a charging station, the chassis is arranged to release the first battery module from the first battery compartment and receive a second battery module within the second battery compartment. The robot is thus designed to simultaneously swap a depleted first battery module with a charged second battery module and quickly return to operation.

A robot with rechargeable and interchangeable batteries. The robot includes a body coupled to a wheel assembly, the wheel assembly including a plurality of wheels and a drive mechanism arranged to move the body along a first set of parallel rails extending in a first direction and a second set of parallel rails extending in a second direction perpendicular to the first direction. The body has a chassis defining a first battery compartment and a second battery compartments with a first battery module disposed within the first battery compartment. When the chassis engages with a charging station, the chassis is arranged to release the first battery module from the first battery compartment and receive a second battery module within the second battery compartment. The robot is thus designed to simultaneously swap a depleted first battery module with a charged second battery module and quickly return to operation.

A system for vehicle power exchange includes at least one power terminal disposable on a ground surface on which a vehicle drives. The power exchange terminal has at least a drop mechanism or a lift mechanism. The drop mechanism is associated with the power exchange terminal for releasing a depleted power cell from a vehicle during its power exchange. The lift mechanism is also associated with a power exchange terminal for inserting a charged power cell into the vehicle during power exchange.

A system for vehicle power exchange includes at least one power terminal disposable on a ground surface on which a vehicle drives. The power exchange terminal has at least a drop mechanism or a lift mechanism. The drop mechanism is associated with the power exchange terminal for releasing a depleted power cell from a vehicle during its power exchange. The lift mechanism is also associated with a power exchange terminal for inserting a charged power cell into the vehicle during power exchange.