Abstract: A main object of the present disclosure is to provide a method for producing an active material wherein a volume variation due to charge/discharge is reduced. The present disclosure achieves the object by providing a method for producing an active material, the method comprising steps of: a preparing step of preparing a LiSi precursor including a Si element and a Li element, and a void forming step of forming a void by extracting the Li element from the LiSi precursor by using a Li extracting solvent, and the LiSi precursor includes a crystal phase of Li22Si5.

Abstract: A charging pad includes a side surface on which a charged terminal device is to be placed face to face. The side surface includes a protruding flat surface portion that is raised from a peripheral edge portion, a power transfer coil that is incorporated in a raised region of the protruding flat surface portion, and a holding mechanism that allows the charged terminal device at a predetermined position with respect to the power transfer coil.

Abstract: A vehicle driving system includes a drive motor-generator connected to a first battery and a second battery via respective relays, a power receiving unit connected to the first battery and the second battery via respective relays and connected to an external power supply, and a controller. The controller is configured to, when the power receiving unit is connected to the external power supply, cause the first battery to be charged if the state of charge of the first battery is lower than a predetermined SOC and cause the second battery to be charged if the state of charge of the first battery is higher than or equal to the predetermined SOC.

Abstract: A charging pad includes a side surface on which a charged terminal device is to be placed face to face. The side surface includes a protruding flat surface portion that is raised from a peripheral edge portion, a power transfer coil that is incorporated in a raised region of the protruding flat surface portion, and a holding mechanism that allows the charged terminal device at a predetermined position with respect to the power transfer coil.

Abstract: A portable charger has a pre-assigned battery ID. The portable charger includes a wireless power receiving device corresponding to a wireless power transfer device, and a communication device being communicable with a mobile communication terminal. The mobile communication terminal stores the battery ID and a user ID in association with each other. The service server stores the battery ID, the user ID, and a validity of a service user's right to receive a chatting service, in association with each other. The service server is configured to acquire the battery ID and the user ID from the mobile communication terminal and execute an authentication process of determining the validity of the service user's right to receive the charging service for the portable charger that is, identified by the acquired battery ID based on the acquired user ID.

Abstract: To shorten a charge time to a battery. A battery control device includes: a discharge controller which controls a discharge from the battery; and a charge controller which controls a charge to the battery. The discharge controller is configured to be capable of performing at least a discharge from the battery to a lower limit SOC determined in advance which is higher than a pre-charge SOC determined in advance. The charge controller is configured to charge the battery at a second charge rate that is lower than a first charge rate determined in advance when a present SOC of the battery is lower than the pre-charge SOC and to charge the battery at the first charge rate when the present SOC of the battery is equal to or higher than the pre-charge SOC.

Abstract: A battery control device includes: a discharge controller which controls discharge from the battery; a charge controller which controls charge to the battery; and a storage which stores a target charge capacity to be charged to the battery. The discharge controller is configured to be capable of performing at least discharge from the battery to a lower limit SOC determined in advance. The charge controller is configured to start a count of the charge capacity at a timing at which a present SOC of the battery becomes equal to the lower limit SOC when charge is started in a state where the present SOC of the battery is lower than the lower limit SOC, and to end the charge to the battery once the charge capacity having been charged after starting the count becomes equal to the target charge capacity stored in the storage.

Abstract: A vehicle driving system includes a drive motor-generator connected to a first battery and a second battery via respective relays, a power receiving unit connected to the first battery and the second battery via respective relays and connected to an external power supply, and a controller. The controller is configured to, when the power receiving unit is connected to the external power supply, cause the first battery to be charged if the state of charge of the first battery is lower than a predetermined SOC and cause the second battery to be charged if the state of charge of the first battery is higher than or equal to the predetermined SOC.

Abstract: A charging system includes a power transfer device and a rapid charging battery. The power transfer device includes a first power transfer unit being compatible with a first charging standard specifying that the rapid charging battery is to be charged at a predetermined current value. The rapid charging battery includes a first charging unit being compatible with the first charging standard, and a second power transfer unit being compatible with a second charging standard specifying that power is to be transferred at a predetermined current value that is lower than the predetermined current value specified by the first charging standard.

Abstract: A main object of the present disclosure is to provide a method for producing an active material wherein a volume variation due to charge/discharge is reduced. The present disclosure achieves the object by providing a method for producing an active material, the method comprising steps of: a preparing step of preparing a LiSi precursor including a Si element and a Li element, and a void forming step of forming a void by extracting the Li element from the LiSi precursor by using a Li extracting solvent, and the LiSi precursor includes a crystal phase of Li22Si5.

Abstract: A main object of the present disclosure is to provide an anode active material of which expansion along with charge is small. The present disclosure achieves the object by providing an anode active material to be used for a battery, wherein the anode active material is a particle in unwoven shape that contains Si fiber, an average particle size D50 of the anode active material is 0.2 ?m or more and 3.6 ?m or less, and the anode active material is amorphous.

Abstract: A manufacturing method for an all-solid-state battery including a positive electrode layer, a negative electrode layer, a solid electrolyte layer, a positive electrode current collector layer, and a negative electrode current collector layer is provided. At least one of the positive and negative electrode layers is an electrode layer containing a sulfide-based solid electrolyte and having a first main surface and a second main surface. The manufacturing method includes: shielding at least a central portion of the first main surface and at least a central portion of the second main surface from an ambient atmosphere; and exposing an outer peripheral portion of the electrode layer to an atmosphere having a dew-point temperature of ?30° C. or higher, with at least the central portion of the first main surface and at least the central portion of the second main surface shielded from the atmosphere.