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.

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.

A server (battery replacement management server) includes: a communication unit (acquisition unit) that acquires number-of-users information (situation information) in a battery replacement apparatus; and a processor (control unit) that adjusts, based on the situation information, an incentive given to a user of the battery replacement apparatus.

A tractor trailer battery system having a battery compartment containing one or more battery units which house one or more battery cells, electrical leads from the battery units to a trailer mounted controller in electrical communication with a cab mounted controller which is in electrical communication an electric motor or hybrid engine system. The battery system allows for either the trailer mounted controller or the cab mounted controller to provide principal communication to the electric motor or hybrid engine system.

A system and method for vehicle power exchange includes both a system for exchanging a container having a power cell associated with the vehicle and an appropriate vehicle which has been adapted for vehicle power exchange. Advantageously, the system includes at least one power exchange power strip, at least one container with charged power cell associated with the power strip and wireless communication associated with the power exchange strip for communicating with a vehicle to effect power exchange. An advantageous vehicle for power exchange has a removable container with power cell, a computer processor for controlling requisite functions of the vehicle during power exchange (i.e. container exchange) and a mechanism which allows for the depositing of a container with depleted power cell and insertion of a replacement container with charged power cell into the vehicle. The method in one form includes receiving a vehicle for power exchange in a first position along a power strip, communicating instructions wirelessly to the vehicle to release a container with depleted power cell from the vehicle at a first position along a power exchange strip, moving the vehicle to a second position along the power exchange strip, and inserting a container with charged power cell associated with the power exchange strip at the second position, into the vehicle.

A selective battery control system includes a battery exchange station and an at least partially electric vehicle communicably coupled to the battery exchange station. The at least partially electric vehicle includes processing circuitry configured to determine a number of batteries needed for a trip, determine if the at least partially electric vehicle has a correct number of batteries, and in response to the at least partially electric vehicle having an incorrect number of batteries, add or remove batteries until the at least partially electric vehicle has the correct number of batteries for the trip.

A selective battery control system includes a battery exchange station and an at least partially electric vehicle communicably coupled to the battery exchange station. The at least partially electric vehicle includes processing circuitry configured to determine a number of batteries needed for a trip, determine if the at least partially electric vehicle has a correct number of batteries, and in response to the at least partially electric vehicle having an incorrect number of batteries, add or remove batteries until the at least partially electric vehicle has the correct number of batteries for the trip.

A vehicle configured to communicate with a server of a cloud system to enable access to use the vehicle via one or more electronic keys is provided. The vehicle includes electronics and a subsystem of the vehicle for enabling unlocking of the vehicle. The subsystem is interfaced with the electronics and a subsystem of the vehicle for enabling starting of the vehicle for use of the vehicle. The vehicle further includes communications circuitry that is interfaced with electronics of the vehicle. The communications circuitry is programmable to communicate with the server of the cloud system and communicate with a mobile device. The communications circuitry of the vehicle is configured to receive a request from the mobile device for unlocking of the vehicle. The request from the mobile device includes a unique access code obtained by the mobile device from the server to enable sending the request to the vehicle. The unique access code is associated with privileges for use of the vehicle. The privileges are defined for the unique access code, and the vehicle is configured to receive information from the server to authenticate the request by the mobile device. And, if the request is authentic, the mobile device is provided with data to enable an electronic key to use the vehicle, and the electronics of the vehicle instructs the subsystem of the vehicle to enable unlocking of the vehicle and enable starting of the vehicle for use of the vehicle via the electronic key consistent with the privileges of the unique access code.

A docking station comprises a connector for releasably connecting a motorised vehicle; and a charging unit that is joined to the connector for supplying resource to the motorised vehicle through the connector. Optionally, the docking station comprises a holder for receiving a scooter; and a hub connector for connecting the scooter. The holder preferably comprises a lock for fastening the scooter, whilst the lock is preferably configured to detachably receive or release the scooter.

A docking station comprises a connector for releasably connecting a motorised vehicle; and a charging unit that is joined to the connector for supplying resource to the motorised vehicle through the connector. Optionally, the docking station comprises a holder for receiving a scooter; and a hub connector for connecting the scooter. The holder preferably comprises a lock for fastening the scooter, whilst the lock is preferably configured to detachably receive or release the scooter.