A charging reservation system includes an operation plan acquisition unit that acquires an operation plan indicating a work place and a work time of a driver who drives an electric vehicle; a charging device management unit that manages management information including a location of a charging device for the electric vehicle and a reservation status of the charging device; and a reservation unit that makes a time period reservation of the charging device that is located at the work place set in the operation plan or on a travel route from the work place to a next work place, based on the management information.

A renewable energy charging system for increasing the charging efficiency of an autonomous vehicle includes a computer programed to predict, in a vehicle at a plurality of locations, an amount of power generation associated with each location. The computer selects one of the locations based at least on the predicted amounts of power generation and moves the vehicle to the selected location.

Single, internally adjustable modular battery systems are provided, for handling power delivery from and to various power systems such as electric vehicles, photovoltaic systems, solar systems, grid-scale battery energy storage systems, home energy storage systems and power walls. Batteries comprise a main fast-charging lithium ion battery (FC), configured to deliver power to the electric vehicle, a supercapacitor-emulating fast-charging lithium ion battery (SCeFC), configured to receive power and deliver power to the FC and/or to the EV and to operate at high rates within a limited operation range of state of charge (SoC), respective module management systems, and a control unit. Both the FC and the SCeFC have anodes based on the same anode active material and the control unit is configured to manage the FC and the SCeFC and manage power delivery to and from the power system(s), to optimize the operation of the FC.

There is provided an information processing apparatus including a travelable information display unit that displays before a discharge, regarding motor-driven movable bodies of a discharge source and a discharge destination driven by using electric power of batteries, information about places to which the motor-driven movable body of the discharge source can move using electric power of the battery left after the discharge by assuming, when information about a discharge amount discharged from the battery of the motor-driven movable body of the discharge source toward the motor-driven movable body of the discharge destination that receives power supply is input, a case in which the discharge amount is discharged from the battery.

Electric vehicle charging stations are in high demand, as the number of electric vehicles on the road is rising. A novel method and apparatus invention effectively manages the charging station parking space by detecting and taking action on ineligible vehicles that are parked for a long time without charging so that others can use the spot. The invention employs multiple ultrasonic sensors to see if the parking space is occupied or not, and a current sensor to see if the parked vehicle is drawing current through the charging cable or not. Depending on those two outcomes, the invention adopts a monitoring process using audio-visual alarm devices and a communication device to notify parking authorities to take action if the parked vehicle is deemed ineligible. The invention also explains the calibration process of ultrasonic sensors for detecting the presence or absence of a vehicle in the parking space.

A system for powering an electric vehicle (EV) includes a battery, a power distribution module, and a battery bypass module. The power distribution module receives power from a charging station, draws power from the battery in a discharging mode, distributes power from the charging station to the battery in a charging mode, and distributes power to a plurality of subsystems of the EV. The battery bypass module is coupled to the battery and the power distribution module. When the battery bypass module is engaged in a charging bypass mode, power distributed by the power distribution module bypasses the battery and is distributed to at least a subset of the plurality of subsystems of the EV.

A charging apparatus for a vehicle where a terminal (1, FIG. 2) is connected to at least one kerbside power/data unit (9) to provide a power (4) and a data connection (5) to the power/data unit (9), the power/data unit (9) being connected to a nearby vehicle (17) to provide power to charge the vehicle (17) and receive data from the vehicle (17). The fact that the kerbside power/data unit (9) can charge a vehicle (17) using power supplied from a terminal (1, FIG. 2) and can transmit data from the vehicle (17) to the terminal (1, FIG. 2) provides the power and data requirements for connected autonomous vehicles at a kerbside location.

Networked utility services handle data-flow in a system to operate electrical vehicle charging stations. In an example, first and second utility companies may operate in first and second respective areas. A user may have a residence in the first area and may have an electric vehicle at a vehicle charging station in the second area. The user may provide identification at the vehicle charging station in the second area, and the user's vehicle may be charged at that location using electricity from the second utility. Data including the user's identification and the electricity consumed in the charging may be sent to the first utility serving the area including the user's residence. The first utility may bill the user for the electricity used to charge the user's vehicle at the remote vehicle charging station. The charging station, both utilities and/or other parties may share in the receipts.

Provided herein are system, methods and apparatuses for controlling replaceable rechargeable batteries powering and an electric vehicle, comprising, receiving battery utilization instructions computed by a remote battery management system for using and/or recharging each of a plurality of replaceable rechargeable batteries installed in an electric vehicle for powering the electric vehicle, and controlling one or more switching circuits configured to electrically couple or de-couple each of the plurality of batteries to each other and/or to an engine of the electric vehicle according to the received battery utilization instructions to use and/or recharge the respective battery.

A system for controlling a group of charging stations for at least one electric vehicle includes a central device charger controller for controlling system operation. A plurality of charging units communicate with the central device charger controller. The plurality of charging units each further comprises charging circuitry for generating a charging current to the at least one electric vehicle responsive to power provided from a local power grid. A connector provides the generated charging current from the charging circuitry to the at least one electric vehicle. At least one interface within the central device charger controller enables communications with the central device charger controller and a plurality of mobile charging applications and controls charging of a connected at least one electric vehicle.