Systems and methods are provided for coordinating and controlling power flow during bidirectional energy transfer events between an electrified vehicle and one or more charging trailers. The systems and methods may prioritize energy transfers between each connected energy unit based on various parameters, including but not limited to battery prognostic information, driving habits/predicted behavior, user preferences, etc. Charge energy may be transferred to the appropriate energy unit using a semi-automated approach to meet customer needs with varying levels of priority according to an energy transfer prioritization control strategy that is derived from the various inputs that are considered.

A method is disclosed for controlling a charge transfer of an electric vehicle using an electric vehicle charging station, a mobile device, and a cloud server. The method includes receiving, at a mobile device, a message for an electric vehicle of a user directly from the electric vehicle charging station, wherein a user of the mobile device is associated with the electric vehicle to be charged. The method also includes receiving the charging control signal from the cloud server via the mobile device at the electric vehicle charging station in response to authorizing a charging control signal using identification information and credit account information received from the mobile device, wherein the charging control signal is configured to adjust a parameter used to draw electric power from the electric vehicle charging station.

The controller retains the supply power before receiving the connection signal in the disconnected state and calculates the remaining charging time, when a connection signal of the disconnection state is received by operating the connection switch while the charging device is charging the power storage device using power from the external power source with the charging device connected to the external power source via the cable device, and further when the connection between the vehicle side connector and the cable side connector is detected by the connection detection device.

A control apparatus is used for an electric electric vehicle. The electric vehicle charges a storage battery with electric power that is supplied while traveling in a power supply lane that is a travelling road on which contactless power supply is able to be performed. The control apparatus for the electric vehicle includes a charging control unit and a range changing unit. The charging control unit controls charging of a storage battery of an electric vehicle such that a charge amount of the storage battery falls within a target range that is a preset range. The range changing unit changes at least one of an upper limit value and a lower limit value of the target range based on a state of the electric vehicle.

An electric vehicle charging station network includes multiple electric vehicle charging stations belonging to multiple charging station hosts. Each host controls one or more charging stations. A charging station network server provides an interface that allows each of the hosts to define one or more pricing specifications for charging electric vehicles on one or more of their electric vehicle charging stations belonging to that host. The pricing specifications are applied to the charging stations such that a cost of charging electric vehicles using those charging stations is calculated according to the pricing specifications.

A power management apparatus manages a facility including a stop space. The stop space includes charge-discharge equipment that performs charge and discharge of a storage battery apparatus provided in an electric mobile body. The power management apparatus includes: a receiver configured to receive a permission message indicating that at least one of the charge or discharge of the storage battery apparatus is permitted; a manager configured to manage a remaining storage amount of the storage battery apparatus for which the at least one of the charge and discharge is permitted by the permission message, when the storage battery apparatus is connected to the charge-discharge equipment; and a controller configured to control the charge-discharge equipment for performing the at least one of the charge and discharge of the storage battery apparatus, based on the remaining storage amount of the storage battery apparatus that is managed by the manager.

According to one aspect, a charging station or a system for adjustment of electric vehicle (EV) charging timing, power, or location in coordination with the electrical grid (V1G) or vehicle to grid bidirectional power flow (V2G) selection may include a memory, a processor, and a charge controller or controller. The memory may receive a profile associated with an electric vehicle (EV). The profile may be indicative of a V1G/V2G charging schedule preference for the EV. The processor may determine a presence of the EV and the charge controller may control charging of a battery of the EV by selecting V1G or V2G based on the profile and in accordance with the V1G/V2G charging schedule preference.

A computer-implemented method for scheduling pre-departure charging for electric vehicles includes predicting a user-departure time based on a first machine learning prediction model. The method further includes determining a cabin temperature to be set for the user at the user-departure time based on a second machine learning prediction model. The method further includes determining a battery-temperature to be set at the user-departure time based on a third machine learning prediction model. The method further includes determining a present charge level of a battery of the electric vehicle. The method further includes computing a charging start-time to start charging the battery based on one or more attributes of a charging station to which the electric vehicle is coupled, and based on the user-departure time, the cabin temperature, and the battery-temperature. The method further includes initiating charging the battery at the charging start-time.

A method for determining an availability of an electric vehicle charging station is disclosed. The method includes: obtaining a distance between a mobile device and the electric vehicle charging station using a first geolocation information and a second geolocation information; based on the determined distance, determining an availability of the electric vehicle charging station; and sending a message to a user regarding the determined availability of the electric vehicle charging station.

A system for controlling a charging of an electric vehicle, wherein a charging at one electric vehicle charging station affect a charging at another electric vehicle charging station is disclosed. The system includes: an electric power grid, a first electric vehicle charging station connected to the electric power grid, and a second electric vehicle charging station connected to the electric power grid, wherein the first electric vehicle charging station facilitates a charge transfer for an electric vehicle at the second electric vehicle charging station using a mobile device. The mobile device relays communication from the electric vehicle charging stations to the cloud server. The charge transfer request received at the cloud server is authorized using identification information and credit account information received from the mobile device. The charge transfer at the first electric vehicle charging station is adjusted based on a charging level at the second electric vehicle charging station.