A charging assistance system includes a processor configured to execute a generation process of generating charging plan data for a vehicle on the basis of: predicted power consumption of the vehicle calculated on the basis of a future traveling schedule of the vehicle; and a charging condition at each predicted stop place based on the traveling schedule.

A method of prompting an operator of an electric vehicle for pre-conditioning the electric vehicle comprises monitoring a location of the electric vehicle, monitoring the temperature of an electric propulsion system within the electric vehicle, accessing historical data of driving patterns for the electric vehicle, monitoring the location of the operator of the electric vehicle, identifying a condition that indicates imminent usage of the electric vehicle based on the location of the vehicle, the location of the operator of the electric vehicle, and the historical data of driving patterns for the electric vehicle, comparing the temperature of the electric propulsion system of the electric vehicle to a pre-determined preferred operating temperature, and sending a prompt to the operator of the electric vehicle suggesting that pre-conditioning of the electric vehicle may be appropriate.

The present application discloses a thermal management method for a battery pack. The method includes: under a condition that an electric vehicle is in a stationary state, obtaining a power-on time of the battery pack in the electric vehicle; under a condition of determining that the battery pack has a thermal management demand, determining a target temperature of the battery pack according to a connection state of a charging interface of the electric vehicle and a charging device; determining a thermal management starting time of the battery pack based on the target temperature of the battery pack and the power-on time; and under a condition that the thermal management starting time arrives, performing thermal management on the battery pack so that a temperature of the battery pack reaches the target temperature before the power-on time arrives.

A system for charging electric vehicles includes an optimization module configured to construct a charging profile representing a first charging power suitable for being supplied by the charging device in order to charge an electric vehicle, a regulation module for regulating the electric power supplied by the charging device. There is a first mode of operation in which the regulation module applies the charging profile and a second mode of operation in which the device supplies a second charging power. The system further includes a coordination device for communicating with the charging devices, which is suitable for triggering a coordinated optimization phase during which charging devices construct a charging profile from an individual charging data item and for triggering a coordinated regulation phase during which some of the charging devices implement the second mode of operation.

A method for planning a power exchange between a charging infrastructure and an electricity supply grid. The infrastructure has a plurality of terminals for connecting and charging electric vehicles such that the electric vehicles can exchange power with the grid via the terminals. Each electric vehicle has an electrical storage unit with a variable individual state of charge for drawing and outputting power, and all of the storage units connected to the infrastructure form an overall storage unit of the infrastructure, which overall storage unit is characterized by a total storage capacity and a total state of charge that are variable. The prediction of arrival times of the vehicles at the terminals thereof is created, and a total state of charge prediction is created for a prediction period depending on the prediction of the arrival times, wherein the total state of charge prediction is created as a time profile.

Systems and methods for providing a personalized charging rate are provided. In one embodiment, a system may include a recognition module, a schedule module, a charge rate module, and a charging module. The recognition module is configured to identify a vehicle to receive a charge from a charging station. The schedule module is configured to determine a parked period when the vehicle will be present at the charging station based on a schedule. The charge rate module is configured to calculate a personalized charging rate based on the parked period. The charge rate defines a charge period that is an amount of time that the charging station will provide charge to the vehicle. The personalized charging rate is calculated to reduce a time difference between the parked period and the charge period. The charging module is configured to set the personalized charging rate.

A method for heat preservation of a battery of a vehicle by feeding electric power is provided. This method includes: determining an expected vehicle usage time after charging of the battery of the vehicle has been completed and an expected activation time of a function of heating by feeding electric power for heating the battery; and controlling, when the expected activation time is reached, the vehicle to activate the function of heating by feeding electric power according to a current temperature of the battery and the expected vehicle usage time in order that the current temperature of the battery reaches a safety temperature upper threshold to complete heat preservation for the battery. According to the method in the present disclosure, an influence of low temperature on the battery will be avoided, and a waste of electric energy caused due to continuous heating of the battery may be avoided.

A server includes a processor configured to: acquire user schedule information indicating an action schedule of a user and other person schedule information indicating an action schedule of another person associated with the user; estimate, based on the user schedule information, a power amount for a moving object that the user is allowed to use, the moving object including a rechargeable secondary battery; and control a charging device to charge the moving object based on the power amount and the other person schedule information.

A vehicle includes an electric-device temperature acquisition unit, a charging controller, and a predicted charging time deriving unit. The electric-device temperature acquisition unit acquires a temperature of an electric device disposed in a current path for external charging for supplying electric power from a power supply external to the vehicle to a battery mounted in the vehicle. The charging controller pauses a supply of electric power to the battery in response to the temperature of the electric device becoming greater than or equal to a first threshold during the external charging, and resumes the supply of electric power to the battery in response to the temperature of the electric device becoming less than a second threshold lower than the first threshold. The predicted charging time deriving unit derives a predicted charging time predicted to be taken for the external charging in accordance with an instruction for the external charging.

A system for adaptive polling to minimize energy usage while also providing a reasonable quality of service. The system includes one or more processors and a memory device that stores instructions thereon that when executed by the one or more processors, causes one or more of the one or more processors to execute the following operations: receive adaptive polling input information that includes frequency adjustment factors; calculates a polling frequency to poll an electrical device using frequency adjustment factors that include current state of the electrical device, length of time the electrical device has been in the current state, time of day, user scheduled leave time of the electrical device, demand response events; and send polling requests to the electrical device according to the calculated polling frequency. In the context of applications and cloud services that interact with electrical devices, the adaptive polling system polls electrical devices to read device state and optionally to control some aspect of the electrical device's function, such as starting or stopping the device's duty cycle or starting and stopping charging of the electrical devices.