One aspect of the present invention pertains to a method of charging electric storage devices such as batteries. Another aspect of the present invention pertains to a system for charging electric storage devices such as batteries. Another aspect of the present invention pertains to a mobile apparatus for charging electric storage devices such as batteries.

The present disclosure provides a new and improved method and apparatus of scheduling for a charging infrastructure serving a plurality of electric vehicles. A computer-implemented method for scheduling a charging infrastructure serving a plurality of electric vehicles is provided, in which a prediction for a usage pattern of the charging infrastructure is made with a context based on historical usage patterns of the charging infrastructure and the contexts of the historical usage patterns, and a schedule scheme for deciding a distribution of charging spots of the charging infrastructure among the electric vehicles is determined based on the predicted usage pattern.

An electric vehicle (EV) charging system includes a number of output connections (e.g., cables). Each of the output connections is connected to at least one head, and each head can be connected concurrently to an EV. A controller can direct a charging current, delivered over a dedicated circuit from an electric power supply, to a first one of the output connections if a first EV is connected to a head connected to the first one of the output connections. Then, the charging current to the first one of the output connections can be stopped, switched to a second one of the output connections, and restarted if a second EV is connected to a head connected to the second one of the output connections.

An apparatus (101) for controlling transfer of data to and/or from a vehicle (201), along with a system, a vehicle, a method, a computer program and a non-transitory computer readable medium are disclosed. The apparatus (101) comprises a control means (102) configured to: determine a state of charge of the energy storage means (203) that is required at the end of a period in which charging of the energy storage means (203) by an external charging means (225) is performable; predict a state of charge of the energy storage means (203) at the end of the period if a transfer of data were to be performed; and enable the transfer of data to be performed during the period in dependence on the predicted state of charge of the energy storage means (203) at the end of the period being greater than or equal to the state of charge required at the end of the period.

Embodiments include methods, for a wireless device, to determine one or more preferred routes for an electric vehicle powered by a battery. Such methods include determining multiple candidate routes from a starting point to a destination. Each candidate route includes one or more segments, each segment associated with a slope and a distance. Such methods include, for each candidate route, estimating a route battery discharge amount and a route duration of travel based on a discharge profile for the battery and the slopes and distances associated with the segments of the candidate route. Such methods include selecting one or more preferred routes, from the candidate routes, based on a current state of charge for the battery, the route battery discharge amounts, and the route durations of travel. Other embodiments include wireless devices configured to perform such methods, and electric vehicles operably coupled to such wireless devices.

Automatic troubleshooting method is provided for a charging device of an electric vehicle. The operation of the charging device is monitored, and when an abnormal situation specified by a predetermined abnormal situation definition is detected, a troubleshooting procedure corresponding to the predetermined abnormal situation definition is performed automatically.

A charge/discharge management apparatus for executing charge/discharge of a battery of a vehicle electrically connected to a facility, comprising an obtaining unit for obtaining use histories of a plurality of batteries corresponding to a plurality of vehicles electrically connected to the facility, and a selection unit for selecting a battery subjected to execution of charge/discharge from the plurality of batteries based on priority decided from the use histories.

Embodiments described herein generally relate to the modification of State of Charge (SoC) calculations within electric vehicles (EVs). A database of data points may be generated based on characteristics of a battery cell at various measured SoCs within a controlled environment. Subsequently, during the operation of an EV, a battery management system (BMS) within the EV may collect various operating data points. The collected operating data points may be utilized to reference similar data points stored in the database in order to determine an SoC value. The SoC value may be utilized to modify or alter the SoC calculations by the BMS for an EV in operation.

An apparatus comprises a power electronic energy conversion system comprising a first energy storage device configured to store DC energy and a first voltage converter configured to convert a second voltage from a remote power supply into a first charging voltage configured to charge the first energy storage device. The apparatus also includes a first controller configured to control the first voltage converter to convert the second voltage into the first charging voltage and to provide the first charging voltage to the first energy storage device during a charging mode of operation and communicate with a second controller located remotely from the power electronic energy conversion system to cause a second charging voltage to be provided to the first energy storage device during the charging mode of operation to rapidly charge the first energy storage device.

High power bidirectional charging systems with a split battery architecture are disclosed. The bidirectional charging systems can include a bidirectional charger and an integrated battery. The bidirectional charger is bidirectional, providing vehicle-to-grid (V2G) energy transfer capability from an electrical grid to an electric vehicle (EV), as well as electrical energy transfer capability from the integrated battery to the power grid and from EV battery to the electrical grid. The integrated battery is split into two sections. A first battery section is a lower voltage battery, which can feed the output direct current (DC) directly without a converter. A second battery section is a higher voltage battery. The output power provided by the charger can exceed voltage limits of the individual electronic components by adding the output of the first integrated battery section with an output of the second integrated battery section.