The present disclosure relates to methods and associated systems for operating a battery exchange station. The present technology (1) receives battery information from a memory attached to each of a plurality of exchangeable batteries positioned in the battery exchange station; (2) receives a battery demand prediction associated with the battery exchange station; and (3) identifying one or more uninterruptible-power-supply (UPS) batteries from the plurality of exchangeable batteries at least partially based in part on the battery demand prediction and individual state of charges (SoCs) of the plurality of exchangeable batteries.

Systems and methods for automated swapping of a charged replacement battery for a depleted battery onboard an electric vehicle using a battery delivery vehicle (BDV). The BDV may be configured to operate autonomously or under remote control. The electric vehicle which receives the replacement battery from a BDV may be configured to operate autonomously (e.g., an AGV) or non-autonomously (e.g., an electric passenger car). The BDV is loaded with a fully (or partially) charged battery, and then moved to a rendezvous place at which the BDV is underneath and aligned with the electric vehicle. The battery is uploaded to the electric vehicle while the aligned BDV moves in tandem with the electric vehicle. After the replacement battery has been installed, the power distribution system onboard the electric vehicle switches over to draw DC power from the replacement battery (instead of from a depleted battery) without interrupting vehicle operation.

Systems and methods for automated swapping of a charged replacement battery for a depleted battery onboard an electric vehicle using a battery delivery vehicle (BDV). The BDV may be configured to operate autonomously or under remote control. The electric vehicle which receives the replacement battery from a BDV may be configured to operate autonomously (e.g., an AGV) or non-autonomously (e.g., an electric passenger car). The BDV is loaded with a fully (or partially) charged battery, and then moved to a rendezvous place at which the BDV is underneath and aligned with the electric vehicle. The battery is uploaded to the electric vehicle while the aligned BDV moves in tandem with the electric vehicle. After the replacement battery has been installed, the power distribution system onboard the electric vehicle switches over to draw DC power from the replacement battery (instead of from a depleted battery) without interrupting vehicle operation.

A system and method for refueling a vehicle are described. An illustrative refueling system is taught to include a lift configured to lift and lower a vehicle frame, a coupling and coupling receiver that releasably connect a wheel to the vehicle frame, and a wheel travel lane that enables a replacement wheel to be rolled underneath the vehicle frame while the vehicle frame is lifted.

A movable battery replacing platform includes a travel-driving portion used for driving the movable battery replacing platform to move on the ground; a lifting portion mounted on the travel-driving portion, for lifting a battery during the replacement of the battery; and a battery mounting portion mounted on the top of the lifting portion, for placing a battery to be replaced or a replaced battery. The battery mounting porting is provided with a battery replacing device. The device can use an unlocking device to unlock a battery locked on the bottom of an electric vehicle, automatically aligning an unlocking point of a battery locking mechanism and realizing automatic unlocking in the movement. The angle of an upper board relative to the battery unlocking position can be adjusted by a movement actuating device, so that the unlocking point of the battery can automatically fit where the movable battery replacing platform remains still.

A movable battery replacing platform includes a travel-driving portion used for driving the movable battery replacing platform to move on the ground; a lifting portion mounted on the travel-driving portion, for lifting a battery during the replacement of the battery; and a battery mounting portion mounted on the top of the lifting portion, for placing a battery to be replaced or a replaced battery. The battery mounting porting is provided with a battery replacing device. The device can use an unlocking device to unlock a battery locked on the bottom of an electric vehicle, automatically aligning an unlocking point of a battery locking mechanism and realizing automatic unlocking in the movement. The angle of an upper board relative to the battery unlocking position can be adjusted by a movement actuating device, so that the unlocking point of the battery can automatically fit where the movable battery replacing platform remains still.

A movable battery replacing platform includes a travel-driving portion used for driving the movable battery replacing platform to move on the ground; a lifting portion mounted on the travel-driving portion, for lifting a battery during the replacement of the battery; and a battery mounting portion mounted on the top of the lifting portion, for placing a battery to be replaced or a replaced battery. The battery mounting porting is provided with a battery replacing device. The device can use an unlocking device to unlock a battery locked on the bottom of an electric vehicle, automatically aligning an unlocking point of a battery locking mechanism and realizing automatic unlocking in the movement. The angle of an upper board relative to the battery unlocking position can be adjusted by a movement actuating device, so that the unlocking point of the battery can automatically fit where the movable battery replacing platform remains still.

A refuse vehicle includes a chassis, a refuse container coupled to the chassis, a tractive assembly coupled to the chassis and configured to propel the refuse vehicle, and an electric energy system configured to provide electrical energy to drive the tractive assembly. In a first configuration, a first energy system is removably coupled to the chassis and configured to provide the electrical energy to the electric energy system and in a second configuration, the first energy system is removed from the chassis and replaced with a second energy system, the second energy system removably coupled to the chassis and configured to provide the electrical energy to the electric energy system.

A refuse vehicle includes a chassis, a refuse container coupled to the chassis, a tractive assembly coupled to the chassis and configured to propel the refuse vehicle, and an electric energy system configured to provide electrical energy to drive the tractive assembly. In a first configuration, a first energy system is removably coupled to the chassis and configured to provide the electrical energy to the electric energy system and in a second configuration, the first energy system is removed from the chassis and replaced with a second energy system, the second energy system removably coupled to the chassis and configured to provide the electrical energy to the electric energy system.

The present disclosure relates to methods and associated systems for providing two energy storage devices positioned in a device-exchange station. The method includes, for example, (1) receiving a request for retrieving two energy storage devices in the device-exchange station; (2) selecting a first energy storage device from a plurality of energy storage devices positioned in the device-exchange station based on characteristic information of each of the energy storage devices; (3) selecting a second energy storage device from the rest of the plurality of energy storage devices positioned in the device-exchange station based on the characteristic information of the first energy storage device and the rest of the plurality of energy storage devices; and (4) releasing the first and second energy storage device.