Abstract: An electric motor gives regenerative braking force to a hybrid vehicle by regenerative control. A regeneration level selector selects regenerative braking force of the electric motor by a driver's operation. When an ECO mode is applied, an ECU increases the regenerative braking force selected by the regeneration level selector as compared with the time when the ECO mode is not applied.

Abstract: An ECU causes a vehicle to travel while selecting one of a CD mode in which an SOC of a power storage device is consumed and a CS mode in which the SOC is maintained to a prescribed level. The ECU controls vehicle driving force to be smaller in the CD mode than in the CS mode at the same accelerator pedal position.

Abstract: A vehicle includes an engine, a motor generator, an electrical storage device, a keeping switch, and a controller. The controller is configured to (a) cause the vehicle to travel by using the output of at least one of the engine and the motor generator, (b) control the state of charge of the electrical storage device, (c) when the keeping mode is requested in response to the signal output from the keeping switch and when the state of charge is higher than a threshold, execute a first keeping control for keeping the state of charge at a current value, and (d) when the keeping mode is requested in response to the signal output from the keeping switch and when the state of charge is lower than the threshold, execute a second keeping control for recovering the state of charge from a current value.

Abstract: In a hybrid vehicle, the charging power of a power storage device can be generated through power generation by a motor generator by using an output of an engine. In response to operation of an SOC recovery switch, an ECU executes SOC recovery control for increasing an SOC of the power storage device to an SOC target value. The SOC target value in the SOC recovery control is set to be higher than an SOC control target when the SOC recovery control is not in execution. The ECU variably sets the SOC target value in the SOC recovery control based on a past driving history of the hybrid vehicle.

Abstract: A hybrid vehicle according to the present invention includes an engine, a power storage device, a motor generator, and an ECU. The motor generator receives electric power from the power storage device and generates travel driving force. The ECU selects one of a CD mode and a CS mode to cause the vehicle to travel, in the CD mode an SOC of the power storage device being consumed, in the CS mode the SOC being maintained within a prescribed range. The CS mode includes a first CS mode and a second CS mode, the first CS mode being selected when the SOC decreases to a prescribed amount, the second CS mode being selected based on a user's intention. A second prescribed range corresponding to the second CS mode is set to be wider than a first prescribed range corresponding to the first CS mode.

Abstract: A display device includes: first setting means for setting a first operation amount to be performed by an occupant so as to increase an output in a state in which a vehicle speed is less than a predetermined threshold; second setting means for setting a second operation amount to be performed by the occupant such that an operation state of the vehicle can be shifted to a desired state in which optimal instantaneous fuel consumption is realized, by decreasing the output in a state in which the vehicle speed is equal to or greater than the predetermined threshold; and display means for displaying, on a display unit, at least one of the first operation amount and the second operation amount, and a present operation amount which is an operation amount performed at present by the occupant.

Abstract: A vehicle includes an engine, a motor generator, an electrical storage device, a keeping switch, and a controller. The controller is configured to (a) cause the vehicle to travel by using the output of at least one of the engine and the motor generator, (b) control the state of charge of the electrical storage device, (c) when the keeping mode is requested in response to the signal output from the keeping switch and when the state of charge) is higher than a threshold, execute a first keeping control for keeping the state of charge at a current value, and (d) when the keeping mode is requested in response to the signal output from the keeping switch and when the state of charge is lower than the threshold, execute a second keeping control for recovering the state of charge from a current value.

Abstract: An ECU causes a vehicle to travel while selecting one of a CD mode in which an SOC of a power storage device is consumed and a CS mode in which the SOC is maintained to a prescribed level. The ECU controls vehicle driving force to be smaller in the CD mode than in the CS mode at the same accelerator pedal position.

Abstract: A display device includes: first setting means for setting a first operation amount to be performed by an occupant so as to increase an output in a state in which a vehicle speed is less than a predetermined threshold; second setting means for setting a second operation amount to be performed by the occupant such that an operation state of the vehicle can be shifted to a desired state in which optimal instantaneous fuel consumption is realized, by decreasing the output in a state in which the vehicle speed is equal to or greater than the predetermined threshold; and display means for displaying, on a display unit, at least one of the first operation amount and the second operation amount, and a present operation amount which is an operation amount performed at present by the occupant.

Abstract: A hybrid vehicle according to the present invention includes an engine, a power storage device, a motor generator, and an ECU. The motor generator receives electric power from the power storage device and generates travel driving force. The ECU selects one of a CD mode and a CS mode to cause the vehicle to travel, in the CD mode an SOC of the power storage device being consumed, in the CS mode the SOC being maintained within a prescribed range. The CS mode includes a first CS mode and a second CS mode, the first CS mode being selected when the SOC decreases to a prescribed amount, the second CS mode being selected based on a user's intention. A second prescribed range corresponding to the second CS mode is set to be wider than a first prescribed range corresponding to the first CS mode.

Abstract: In a hybrid vehicle, the charging power of a power storage device can be generated through power generation by a motor generator by using an output of an engine. In response to operation of an SOC recovery switch, an ECU executes SOC recovery control for increasing an SOC of the power storage device to an SOC target value. The SOC target value in the SOC recovery control is set to be higher than an SOC control target when the SOC recovery control is not in execution. The ECU variably sets the SOC target value in the SOC recovery control based on a past driving history of the hybrid vehicle.

Abstract: An apparatus controls a running state of a hybrid vehicle, wherein the hybrid vehicle is configured to select, as a running mode, an EV running mode and a HV running mode, the hybrid vehicle is configured further to select an intermittent operation mode for repeating acceleration running and coasting by intermittently driving the drive wheels, in the HV running mode. The apparatus switches the EV running mode to the intermittent operation mode according to a comparison result between a power storage amount of the power storing device and a convergence value of the power storage amount in a case where the intermittent operation mode is selected, if the intermittent operation mode is required during steady running by the EV running mode.

Abstract: An electric motor gives regenerative braking force to a hybrid vehicle by regenerative control. A regeneration level selector selects regenerative braking force of the electric motor by a driver's operation. When an ECO mode is applied, an ECU increases the regenerative braking force selected by the regeneration level selector as compared with the time when the ECO mode is not applied.

Abstract: An ECU sets a regenerative braking force generated by a second motor generator during an off-state of an accelerator to be larger in a case where a regeneration level is high than in a case where the selected regeneration level is low, thereby increasing a power generation amount of the second motor generator. The ECU sets a charging amount from first motor generator to battery during operation of an engine to be larger in a case where the regeneration level lower than the default level is selected by regeneration level selector than a case where the regeneration level is not selected by regeneration level selector.

Abstract: A hybrid motor vehicle includes a controller configured to: control an engine and a motor so that when power required of the vehicle increases to or above a first threshold value during stop of the engine, the engine outputs the required power until the required power decreases to or below a second threshold value that is smaller than the first threshold value; control the engine and the motor so that when the required power decreases to or below the second threshold value during operation of the engine, the engine is in a stopped state until the required power increases to or above the first threshold value; and set the second threshold value so that the second threshold value is smaller when degree of degradation of the battery exceeds a threshold value than when the degree of degradation of the batter is less than or equal to the threshold value.

Abstract: A hybrid motor vehicle includes a controller configured to: control an engine and a motor so that when power required of the vehicle increases to or above a first threshold value during stop of the engine, the engine outputs the required power until the required power decreases to or below a second threshold value that is smaller than the first threshold value; control the engine and the motor so that when the required power decreases to or below the second threshold value during operation of the engine, the engine is in a stopped state until the required power increases to or above the first threshold value; and set the second threshold value so that the second threshold value is smaller when degree of degradation of the battery exceeds a threshold value than when the degree of degradation of the batter is less than or equal to the threshold value.

Abstract: According to one embodiment, a fuel cell unit is provided with a unit body including an electromotive section which performs power generation operation, a fuel cartridge removably attached to the unit body and stored with a fuel, a fuel supply line through which the fuel is supplied from the fuel cartridge to the electromotive section, a fuel detecting section configured to detect a property of the fuel in the fuel supply line, and a control section which at least warns about the necessity of replacement of the fuel cartridge or stops the operation of the unit body if the property of the fuel detected by the fuel detecting section is different from a given property.

Abstract: According to one embodiment, a liquid quantity sensing device comprises a sensor body, a first electrode, a plurality of second electrodes and a sensing mechanism. The sensor body extends toward an interior of a container and includes electrically conductive material. The first electrode is disposed on the sensor body while the plurality of second electrodes are disposed on the sensor body and are separated from each other in a movement direction of a liquid level that changes according to a quantity of the liquid. The sensing mechanism senses conduction states between the respective second electrodes and the first electrode. At least one of the first electrode and an uppermost electrode of the second electrodes is separated from the upper wall by a distance larger than a maximum thickness of a liquid drop that adheres to the upper wall.

Abstract: According to one embodiment, there is provided a fuel cell unit capable of generating power by a fuel cell. The fuel cell unit includes a concentration measuring section to measure a concentration of a fuel solution for use in power generation by the fuel cell, a storage section to store a first concentration measurement value obtained from the concentration measuring section when power generation by the fuel cell terminates, and a control section to correct a second concentration measurement value obtained from the concentration measuring section when power generation by the fuel cell starts, if there is a difference of a certain amount or more between the first concentration measurement value stored in the storage section and the second concentration measurement value obtained from the concentration measuring section, to keep the difference under the certain amount.

Abstract: A fuel cell comprises an electromotive section, a fuel tank, a mixing tank in which the fuel supplied from the fuel tank is mixed with water from the electromotive section and an aqueous fuel solution is formed, a first line through which the fuel is circulated between the electromotive section and the mixing tank, a cooler which cools a product from the electromotive section, and a second line through which the aqueous fuel solution is refluxed to the mixing tank through a branch on the first line. A concentration sensor is arranged in the second line and detects a fuel concentration of the aqueous fuel solution in the second line. A valve mechanism for sweeping bubbles is provided in the second line and serves to stop a flow of the aqueous fuel solution in the second line.