There is provided a motor vehicle including a lithium ion capacitor; an electrical load configured to transmit electric power to and from at least the lithium ion capacitor; and a control device. The control device is programmed to control the lithium ion capacitor such as to be charged and discharged according to a discharging excess pattern that provides a higher discharge current value than a charging current value, when a degree of degradation of the lithium ion capacitor reaches or exceeds a predetermined level by charging and discharging the lithium ion capacitor according to a charging excess pattern that provides a higher charging current value than a discharge current value.

A network includes vehicle(s) having a battery pack and vehicle telematics unit (VTU), and a server. A server in communication with the VTUs and remote client device(s) is programmed to receive vehicle information from the VTU, including an energy throughput value defined by charging power delivered to the battery pack during an active charging event. The server receives utility information and a load adjustment request from the remote client device, including a power interrupt permission status describing whether interruption of power by a host of the client device is permitted. Charging control signals are transmitted in response to the load adjustment request to enable or postpone the charging event. Energy throughput is recorded over multiple active charging events, which are then combined or aggregated. Output data, e.g., a bill or report describing the aggregated energy throughput values, may be generated by the server. A method and server are also disclosed.

A battery bracket for attaching, to an electrically assisted moving body capable of supplementing a first driving force generated by human power with a second driving force generated by electrical power, and a battery for use in the electrically assisted moving body. This battery bracket includes an extension section extending in a prescribed direction, and a plurality of projection sections projecting from the extension section in a direction intersecting the prescribed direction. The plurality of projection sections are mutually spaced along the prescribed direction.

A system includes a computing device for receiving information representative of activities of an operating first vehicle that includes a propulsion system. The computing device is configured to produce one or more control parameters from the received information in combination with information received from other vehicles, and, provide the one or more control parameters to control operations of a second vehicle.

A system includes a computing device for receiving information representative of activities of an operating first vehicle that includes a propulsion system. The computing device is configured to produce one or more control parameters from the received information in combination with information received from other vehicles, and, provide the one or more control parameters to control operations of a second vehicle.

A charging system, wherein a movable body has an automatic operation function, the charging system comprises: a movable body managing unit that manages a charging state of the storage battery of the movable body; and a waiting space managing unit that manages a usage state of a plurality of waiting spaces for keeping the movable body waiting, the waiting space managing unit has: a waiting space determining unit that determines, among the plurality of waiting spaces that the waiting space managing unit is managing, a waiting space for keeping the movable body waiting after charging of the movable body has completed, if the movable body managing unit has detected that: (i) charging of the movable body is being started; (ii) charging of the movable body has been started; (iii) charging of the movable body is completing; or (iv) charging of the movable body has completed.

A charging system, wherein a movable body has an automatic operation function, the charging system comprises: a movable body managing unit that manages a charging state of the storage battery of the movable body; and a waiting space managing unit that manages a usage state of a plurality of waiting spaces for keeping the movable body waiting, the waiting space managing unit has: a waiting space determining unit that determines, among the plurality of waiting spaces that the waiting space managing unit is managing, a waiting space for keeping the movable body waiting after charging of the movable body has completed, if the movable body managing unit has detected that: (i) charging of the movable body is being started; (ii) charging of the movable body has been started; (iii) charging of the movable body is completing; or (iv) charging of the movable body has completed.

A wind turbine panel is configured to distribute electricity to a load. The wind turbine panel includes a frame further comprising a first slot having a first slot first end and a first slot second end. A first alternator is located in a first alternator mount on the first slot first end. A second alternator is located in a second alternator mount on the first slot second end. A wind turbine is connected to the first alternator and the second alternator via a first alternator shaft and a second alternator shaft, respectively. The first alternator and the second alternator are electrically coupled to an electrical outlet point on the frame. Wind traveling through the frame rotates the wind turbine, impels the alternator shafts to generate electricity which is then transferred to an electrical outlet point and further to an electrical panel for use in a plurality of downstream applications.

Charge efficiency of normal charge is improved without restricting an operation of a low-voltage load of an electric vehicle during the normal charge. During a charge of a high-voltage battery of a vehicle, when a determination of the normal charge is made, and when a determination that a mode switching target load is not operated is made, power saving mode transition processing is performed. Therefore, an operating mode of a DC-DC converter, which steps down a voltage at the high-voltage battery and supplies the stepped-down voltage to a low-voltage battery and a low-voltage load, is set to a power saving mode in which consumption power is reduced compared with a normal mode. When a determination that a start-up manipulation of the mode switching target load is performed is made, the operating mode of the DC-DC converter is changed to the normal mode.

A method is provided for notifying a driver that charging is required determined by utilizing the calculated remaining travel distance of the vehicle, the position information of the charging station and the position information about the destination. In particular, the method determines when the total travel distance in consideration of the destination exceeds the remaining travel distance of the vehicle. The driver is notified of the necessity for charging during the initial traveling, and before traveling beyond the rechargeable returning distance.