Abstract: A hybrid vehicle includes: a catalytic device configured to be electrically heatable to purify exhaust gas of an internal combustion engine; a main power supply device that supplies the motor drive unit with power supply voltage; a power supply device provided for a catalyst, and receiving electric power from the main power supply device and supplying the catalytic device with electric power to heat the catalytic device; and a control device. The control device has a first control mode and a second control mode more immune to variation of the power supply voltage than the first control mode as modes applied to control the motor drive unit. If electric power supplied to the catalytic device from the power supply device for the catalyst is to be changed, the control device previously controls the motor drive unit in the second control mode.

Abstract: An electrically powered vehicle has a main battery and an auxiliary battery mounted therein. In external charging, a charging device performs AC/DC power conversion converting power received from an external power supply into power charged to main battery. A sub charging relay is connected between a predetermined node on an electric conduction path of the charging device in the AC/DC power conversion and the auxiliary battery. The sub charging relay is turned off in the external charging. The charging device is configured such that when the external charging is not performed and the sub charging relay is turned on the charging device performs DC/DC power conversion to convert power of the main battery via at least a portion of the electric conduction path in the AC/DC power conversion into power to be charged to the auxiliary battery and outputs the converted power on the predetermined node.

Abstract: An electric load is electrically connected to a path between an external power supply and a power storage device. An ECU executes temperature-rise control, when the temperature of the power storage device is low, ensuring power consumption of the electric load in association with charging/discharging of the power storage device. During execution of temperature-rise control, the ECU sets a power command value of the external charger, alternately causing a discharging mode having the output power of the external charger positively controlled and in which power consumption of the electric load is ensured in association with discharging of the power storage device, and a charging mode having the output power of the external charger negatively controlled and in which power consumption of the electric load is ensured in association with charging of the power storage device.

Abstract: A vehicle is equipped with a main battery, an auxiliary machinery battery, a high-capacitance DC/DC converter which converts power on an electric path between the main battery and a motor-generator for traveling to supply the converted power to the auxiliary machinery battery, a low-capacitance sub power supply which converts power on an electric path between the main battery and an external power supply to supply the converted power to the auxiliary machinery battery, and a control device which controls the sub power supply. The control device determines whether or not the DC/DC converter has an abnormality, and operates the sub power supply to perform precharging when it is determined that the DC/DC converter is abnormal. An auxiliary machinery battery voltage V2 when precharging has been performed is set to a value which is higher by a predetermined voltage a than an auxiliary machinery battery voltage V1 when precharging has not been performed.

Abstract: A charger converting electric power from an external power supply into charging power for a power storage device converts AC power on a power line into charging power for an auxiliary battery. A CHR connects or disconnects a path between the charger and the power storage device. A DC/DC converter converts DC power on a power line connected to a smoothing capacitor into charging power for the auxiliary battery and outputs the power onto a power line. An ECU discharges the smoothing capacitor even if the voltage on the power line is lower than a determination voltage by causing the DC/DC converter to operate to charge the auxiliary battery in a discharging mode where the CHR is set OFF.

Abstract: A switching relay is configured to switch between a first power feeding path for feeding power from a charge inlet to an outlet and a second power feeding path for feeding power from a power storage device to the outlet. A PM-ECU controls the switching relay to switch between the first power feeding path and the second power feeding path, based on a result of comparison between a power cost in a case where the power is fed to the outlet through the first power feeding path and a power cost in a case where the power is fed to the outlet through the second power feeding path.

Abstract: A charge device converting electric power from an external power supply into a charging electric power for a power storage device is configured to allow power conversion bidirectionally. An AC/DC converter of an external charging system converts AC power of a power line into a charging electric power for an auxiliary battery. A DC/DC converter of the vehicle running system converts the electric power from the power storage device into the charging power for the auxiliary battery. When charging of the auxiliary battery is requested, a control device selectively executes a first charge of converting the electric power of the power storage device by the DC/DC converter to charge the auxiliary battery, and a second charge of converting the electric power of the power storage device by a charge device and the AC/DC converter to charge the auxiliary battery, according to an output state of the auxiliary battery.

Abstract: A charger converts electric power supplied from an AC power supply external to a vehicle into a predetermined charging voltage. A relay is provided between the charger and a power storage device. A charging ECU controls the charger and the relay. An AC/DC converter converts electric power supplied from the AC power supply into a predetermined power supply voltage and supplies the electric power converted into the power supply voltage to a charging device constituted of the charger, the relay and the charging ECU. While the power storage device is charged by the AC power supply, the charging device operates with the operating electric power it receives from the AC/DC converter.

Abstract: A power supply system includes: a first electrical storage device; a charging device charging the first electrical storage device with external power from an external power supply; a second electrical storage device supplying an auxiliary load with a voltage lower than an output voltage of the first electrical storage device; a first converter stepping down a voltage of power from the first electrical storage device and supplying the auxiliary load and the second electrical storage device with a voltage; a second converter having a capacity smaller than that of the first converter and charging the second electrical storage device with the external power; and a controller, when the external power is charged, controlling charging power from the charging device to the first electrical storage device and charging power from the second converter to the second electrical storage device based on a state of charge of the second electrical storage device.

Abstract: A hybrid vehicle (100) includes a voltage step-up device (17). The voltage step-up device (17) is provided between driving devices (18, 20) and an electrical storage device (16), and steps up input voltages of the driving devices (18, 20) to a voltage of the electrical storage device (16) or above. An HV-ECU (36) determines whether it is possible to reduce a CO2 emissions for a predetermined travel route by increasing the voltage of the electrical storage device (16). Then, when it is determined that it is possible to reduce the CO2 emissions, the HV-ECU (36) controls an SOC of the electrical storage device (16) so as to increase the SOC at a start of the travel route.

Abstract: A charger electrically charges a main battery via an electric power conversion path extending through an isolation transformer and providing electrical isolation between an external power supply and the main battery when first and second relays are turned off and a relay is turned on. In contrast, the charger electrically charges the main battery via an electric power conversion path bypassing the isolation transformer and providing electrical connection between the external power supply and the main battery when the first and second relays are turned on and the third relay is turned off. The charger can thus selectively apply employing the isolation transformer to ensure electrical isolation in externally electrically charging the battery, and bypassing the isolation transformer to give priority to high efficiency in externally electrically charging the battery, as the relays are turned on/off as controlled.

Abstract: A conversion adaptor enables utilization of a standardized charge cable used when a power storage device mounted on an electrically-powered vehicle is charged by a power source provided outside of the vehicle as a universal cable for transmitting electric power to electric loads having different plug shapes that are respectively standardized from one region to another. Conversion adaptor includes a primary side connector unit configured to be connectable to a connector of charge cable, a secondary side connector unit configured so as to have a plug of an electric load, such as a home electric appliance, connected thereto, and a manipulating unit for manipulating a CCID of charge cable so that relays are switched off when connector of charge cable is connected to first connector unit.

Abstract: A power supply system or a vehicle includes: a first storage device; a charging device charging the first storage device with external power; a second storage device supplying an auxiliary load with a voltage lower than an output voltage of the first storage device; a first converter stepping down a voltage of power from the first storage device and supplying the auxiliary load and the second storage device with a voltage; a first controller controlling the charging device; a second converter smaller in capacity than the first converter, supplying the first controller with a voltage and charging the second storage device with the external power; and a second controller, when the external power is charged, controlling the first and second converters to selectively operate any one of the first and second converters based on a state of charge of the second storage device and a state of the auxiliary load.

Abstract: A vehicle includes a PCU controlling electric power supplied to a motor, a first power storage device, a second power storage device, an ECU, a charger, system main relays SMR1 to SMR4, SMRA, SMRB, and charging relays CR1 to CR4. The first power storage device is formed such that a first module and a second module which are separately disposed are connected in series through SMRA and SMRB. The first power storage device is connected to the PCU through SMR1 and SMR2. The second power storage device is connected to the PCU through SMR3 and SMR4. The charger has a capacitor that is connected to the first power storage device through CR1 and CR2 and also connected to the second power storage device through CR3 and CR4. When charging is completed, the ECU turns on CR1, CR2, SMR1, and SMR2, and turns off SMRA, SMRB, CR3, CR4, SMR3, and SMR4.

Abstract: A power supply device includes: a magnetic-coupling-type multi-phase converter having first and second chopper circuits that respectively adjust respective currents flowing in first and second reactors magnetically coupled to each other, and performing voltage conversion between a DC power supply and a load; and a control circuit. The control circuit includes a determination unit and a current control unit. The determination unit determines whether the temperature of the power supply is lower than a reference temperature. In the case where the power supply temperature is lower than the reference temperature, the current control unit uses a value determined by adding an offset amount to a detected value of the reactor current to set a duty command value for the first chopper circuit and uses a detected value of the reactor current to set a duty command value for the second chopper circuit.

Abstract: A hybrid vehicle includes: a catalytic device configured to be electrically heatable to purify exhaust gas of an internal combustion engine; a main power supply device that supplies the motor drive unit with power supply voltage; a power supply device provided for a catalyst, and receiving electric power from the main power supply device and supplying the catalytic device with electric power to heat the catalytic device; and a control device. The control device has a first control mode and a second control mode more immune to variation of the power supply voltage than the first control mode as modes applied to control the motor drive unit. If electric power supplied to the catalytic device from the power supply device for the catalyst is to be changed, the control device previously controls the motor drive unit in the second control mode.

Abstract: First and second converters are connected in parallel to positive and negative lines, respectively. When a required power is smaller than a reference value, an ECU controls the first and second converters such that one of the first and second converters operates and the other stops. When the required power is equal to or larger than the reference value, the ECU controls the first and second converters such that both the first and second converters operate.

Abstract: A ripple current characteristic of a magnetic-coupling-type multi-phase converter includes a local minimum of the ripple current, with respect to a change of the duty ratio. In a region and another region, the ripple current is larger than a predetermined level. In the case where it is necessary to enhance the responsiveness of the multi-phase converter, a control circuit sets a voltage command value for the multi-phase converter, in accordance with the ripple current characteristic, so that the duty ratio is limited to a value that makes the ripple current larger than the predetermined level.

Abstract: A vehicle control method having an HV driving mode in which operation of an internal combustion engine is permitted and an EV driving mode in which a vehicle is driven by using a motor with the internal combustion engine stopped includes the steps of: setting a destination; setting a driving route from a starting point to the destination; dividing the driving route and associating any of the driving modes with each section of the divided driving route; fixing the division of the driving route and the driving mode associated with each section based on an instruction from an operator; and causing the vehicle to travel each section in the associated driving mode.

Abstract: An AC/DC converter is configured to perform voltage conversion on power supplied from an AC power supply and supply the power to an auxiliary load during external charging in which a main power storage device is charged by the AC power supply. An auxiliary power storage device stores power to be supplied to the auxiliary load. A diode permits discharging of the auxiliary power storage device while preventing charging of the auxiliary power storage device during the external charging. A current sensor detects discharging of the auxiliary power storage device. A controller adjusts an output voltage of the AC/DC converter while confirming whether or not the auxiliary power storage device discharges, based on a detection value of the current sensor.