Abstract: A method of producing a negative electrode includes at least the following (A) to (C): (A) mixing powder consisting of lithium titanate oxide particles, a binder, and a solvent to prepare a particle-dispersed liquid; (B) granulating powder consisting of graphite-based particles by using the particle-dispersed liquid to prepare wet granules; and (C) forming the wet granules into a negative electrode composite material layer to produce a negative electrode. The negative electrode composite material layer is formed so as to include the lithium titanate oxide particles in an amount not lower than 2 mass % and not higher than 15 mass % of the total amount of the graphite-based particles and the lithium titanate oxide particles.

Abstract: A power transmitting device includes a power transmission unit using contactless power supply, processing circuitry configured to switch a power transmission mode of the power transmission unit between a normal output mode and a limit mode, and a transmission-side communication unit configured to execute communication with a power receiving device. The processing circuitry is configured to determine whether the power receiving device is a registered power receiving device based on information related to the power receiving device obtained from the transmission-side communication unit, determine whether the registered power receiving device is located inside a power transmission range of the power transmission unit, set the power transmission mode to the normal output mode when determining that the registered power receiving device is located inside the range, and set the power transmission mode to the limit mode when determining that the registered power receiving device is not located inside the range.

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 power transmitting device includes a power transmission unit using contactless power supply, processing circuitry configured to switch a power transmission mode of the power transmission unit between a normal output mode and a limit mode, and a transmission-side communication unit configured to execute communication with a power receiving device. The processing circuitry is configured to determine whether the power receiving device is a registered power receiving device based on information related to the power receiving device obtained from the transmission-side communication unit, determine whether the registered power receiving device is located inside a power transmission range of the power transmission unit, set the power transmission mode to the normal output mode when determining that the registered power receiving device is located inside the range, and set the power transmission mode to the limit mode when determining that the registered power receiving device is not located inside the range.

Abstract: An electronic device includes a power receiving device, a reception-side power storage unit configured to store power received by the power receiving device, a drive unit configured to be activated together with the power receiving device by the power stored in the reception-side power storage unit, a notification unit configured to notify a user of a state of the power in the reception-side power storage unit, a first power measurement unit configured to measure supplied power, a second power measurement unit configured to measure power consumption, and circuitry configured to change a notification mode in the notification unit based on a relationship between the supplied power and the power consumption.

Abstract: A power transmitting device performs power transmission to a power receiving device. The power receiving device is provided in a space that a person can enter or exit. The power transmitting device includes a power transmitting unit, a processing circuitry, and a reception unit. The power transmitting unit is configured to perform power transmission to the power receiving device through contactless power supply. The processing circuitry is configured to switch a power transmission mode of the power transmitting unit between a normal-output mode and a limit mode in which a transmitted power is more limited than in the normal-output mode. The reception unit is configured to receive a limit instruction for the power transmission given by the person. The processing circuitry is configured to set the power transmission mode to the limit mode when the reception unit receives the limit instruction.

Abstract: A contactless power supply system includes one or more power receiving devices, a power transmitting device, and a determining unit. The power receiving devices each include a transmitting unit and a power receiving unit. The power transmitting device includes a receiving unit and a power supplying unit. The determining unit is configured to determine, based on a prevention condition information that represents a prevention condition, whether the power receiving device that has transmitted the beacon signal satisfies the prevention condition. The power received by the power receiving device is prevented from increasing when the prevention condition is satisfied. The power supplying unit is configured to reduce power supply to the power receiving device that satisfies the prevention condition based on a determination result of the determining unit.

Abstract: A power transmitting device is configured to perform contactless power supply using a power transfer signal to a power receiving device that supplies power to a power supply target. The power transmitting device includes a power transmitting antenna, a region indicator unit, and processing circuitry. The power transmitting antenna is configured to transmit a power transfer signal to the power receiving device. The region indicator unit emits a visible beam. Based on a transmitted power that is transmitted as the power transfer signal, the processing circuitry derives a power receivable region, in which the power receiving device is capable of receiving the power transfer signal as a received power greater than or equal to a specified threshold. The processing circuitry uses the region indicator unit to emit the visible beam toward at least a part of the power receivable region.

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: 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: 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 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 method of producing a secondary battery includes an electrode body forming process and a resistance welding process. In the electrode body forming process, a sheet-like positive electrode and negative electrode are wound in an overlapping manner with a separator therebetween to form a flat wound electrode body. In the resistance welding process, a current collector terminal is bonded to at least one of a pair of uncoated parts which are positioned at both ends of the wound electrode body in a winding axis direction and to which no electrode mixture is applied by resistance welding. The resistance welding process is performed while metal members are brought into contact with the uncoated parts.

Abstract: A method of producing a negative electrode includes at least the following (A) to (C): (A) mixing powder consisting of lithium titanate oxide particles, a binder, and a solvent to prepare a particle-dispersed liquid; (B) granulating powder consisting of graphite-based particles by using the particle-dispersed liquid to prepare wet granules; and (C) forming the wet granules into a negative electrode composite material layer to produce a negative electrode. The negative electrode composite material layer is formed so as to include the lithium titanate oxide particles in an amount not lower than 2 mass % and not higher than 15 mass % of the total amount of the graphite-based particles and the lithium titanate oxide particles.

Abstract: A method of producing a non-aqueous electrolyte secondary battery includes at least the following (?), (?), and (?): (?) preparing an elementary battery including at least a positive electrode, a negative electrode, a gel film, and an electrolyte solution; (?) carrying out initial charge of the elementary battery; and (?) after the initial charge, processing the elementary battery to produce a finished-product battery. The negative electrode includes at least a negative electrode active material. The gel film is formed on a surface of the negative electrode. The gel film contains a polymer material and the electrolyte solution. The gel film is thixotropic. The initial charge is carried out while the gel film is under a first pressure. The processing is carried out in such a way that the gel film is put under a second pressure. The second pressure is higher than the first pressure.

Abstract: A method of producing a negative electrode includes at least the following (A) to (C): (A) mixing powder consisting of lithium titanate oxide particles, a binder, and a solvent to prepare a particle-dispersed liquid; (B) granulating powder consisting of graphite-based particles by using the particle-dispersed liquid to prepare wet granules; and (C) forming the wet granules into a negative electrode composite material layer to produce a negative electrode. The negative electrode composite material layer is formed so as to include the lithium titanate oxide particles in an amount not lower than 2 mass % and not higher than 15 mass % of the total amount of the graphite-based particles and the lithium titanate oxide particles.

Abstract: The present invention provides a method for manufacturing a battery which includes a granulation step (Step S1) of mixing at least an active material, a binder, and a solvent to form wet granulated particles, a deposition step (Step S2) of subjecting the wet granulated particles to a forming process to form an active material layer on a current collector, a rolling step (Step S3) of placing a separator on a surface of the active material layer and rolling the separator before the wet granulated particles on the current collector are dried, to obtain a laminated body in which the current collector, the active material layer, and the separator are stacked in this order and closely attached to each other, a drying step (Step S4) of drying the laminated body to provide an integrated laminated body, and a fabrication step (Step S5) of fabricating a battery using the integrated laminated body.