Abstract: A control apparatus is applied to a hybrid vehicle including an internal combustion engine that is capable of changing over its combustion state between lean combustion and stoichiometric combustion. The control apparatus executes noise suppression control by limiting the operating point of the internal combustion engine to be upon a noise suppression line for lean combustion or to be upon a noise suppression line for stoichiometric combustion, so that the noise generated by a power transmission mechanism is suppressed. When changing over from lean combustion to stoichiometric combustion during execution of noise suppression control, the control apparatus of the present invention changes the air/fuel ratio after changing the operating point of the internal combustion engine from one point to a point that is more toward the lower torque side of the noise suppression line.

Abstract: An electronic control unit included in a control system is configured to execute a change of a combustion mode in an inertia-phase period during a gear shift operation, or after the gear shift operation is completed, when a request for the change of the combustion mode and a request for a gear shift of the transmission mechanism overlap. The electronic control unit is configured to execute the change of the combustion mode in the inertia-phase period during the gear shift operation when conditions i) and ii) are established, and execute the change of the combustion mode after the gear shift operation is completed when conditions i) and iii) are established. The aforementioned conditions include: i) the change of the combustion mode is accompanied by an increase in engine power; ii) the power running mode is executed during the gear shift operation; and iii) the regeneration mode is executed during the gear shift operation.

Abstract: A control device according to the invention moves an operation point of an internal combustion engine such that a distribution of engine torque with respect to required torque is reduced and then carries out air-fuel ratio control for reducing an air-fuel ratio of the internal combustion engine in a case where an operation mode of the internal combustion engine should be switched from a lean combustion mode to a stoichiometric combustion mode.

Abstract: An electronic control unit included in a control system is configured to execute a change of a combustion mode in an inertia-phase period during a gear shift operation, or after the gear shift operation is completed, when a request for the change of the combustion mode and a request for a gear shift of the transmission mechanism overlap. The electronic control unit is configured to execute the change of the combustion mode in the inertia-phase period during the gear shift operation when conditions i) and ii) are established, and execute the change of the combustion mode after the gear shift operation is completed when conditions i) and iii) are established. The aforementioned conditions include: i) the change of the combustion mode is accompanied by an increase in engine power; ii) the power running mode is executed during the gear shift operation; and iii) the regeneration mode is executed during the gear shift operation.

Abstract: A control apparatus for a hybrid vehicle is provided with a first charge controlling device configured to maintain output of an internal combustion engine at a predetermined value or more, and to charge a power storing device with an output excess with respect to an output request for the internal combustion engine. The control apparatus includes a second charge controlling device configured to charge the power storing device with an output increment caused by upshift of a gear shifting device. The control apparatus further includes a transmission time changing device configured to extend an execution time of the upshift or to delay start timing of the upshift, in order to prevent charge power for the power storing device from exceeding an input limit value for the power storing device, if the control time of the output reduction request overlaps the control time of the upshift request.

Abstract: The control apparatus of the present invention is applied to a hybrid vehicle that, as power sources for propulsion, includes an internal combustion engine that can change over between lean combustion and stoichiometric combustion, and motor-generators. The control apparatus performs the noise suppression control in which the operating points of the internal combustion engine are limited so as to suppress noise generated by a power transmission mechanism, and changes over the operational mode of the internal combustion engine if the thermal efficiency when performing the noise suppression control by changing over the operational mode of the internal combustion engine is higher than the thermal efficiency when performing the noise suppression control by keeping the operational mode of the internal combustion engine the same.

Abstract: A control apparatus, which is configured to control a hybrid vehicle, is provided with: a device configured to determine whether or not there is a response delay of the supercharger; a device configured to control torque of the rotary electric machine to compensate for an insufficiency of torque of a drive shaft if there is the response delay when an output limit value of the battery is greater than or equal to a predetermined value; a device configured to estimate a NOx storage amount in the NOx storage/reduction catalyst; and a device configured to control an air-fuel ratio of the internal combustion engine to be rich if the NOx storage amount is greater than or equal to a predetermined value, or if there is the response delay when the output limit value of the battery is less than the predetermined value.

Abstract: A control device according to the invention moves an operation point of an internal combustion engine such that a distribution of engine torque with respect to required torque is reduced and then carries out air-fuel ratio control for reducing an air-fuel ratio of the internal combustion engine in a case where an operation mode of the internal combustion engine should be switched from a lean combustion mode to a stoichiometric combustion mode.

Abstract: The control apparatus of the present invention is applied to a hybrid vehicle having an internal combustion engine that is capable, during operation, of changing over its operational mode to lean combustion or to stoichiometric combustion. The control apparatus preferentially selects an operational mode having high system efficiency in relation to the requested power, and selects the stoichiometric combustion mode (S104) when, under the specific condition that the system efficiency is higher in the lean combustion mode as compared to the EV mode and moreover is lower in the stoichiometric combustion mode as compared to the EV mode, also the temperature (Tnc) of an exhaust purification catalyst is less than or equal to a first predetermined value (T?) (S101, S102).

Abstract: A control apparatus for a vehicle is provided. The vehicle includes an engine and a transmission. The transmission is configured to continuously change an engine operating point that is defined by a rotational speed of the engine and a torque of the engine. The control apparatus includes an ECU. The ECU is configured to, when a target engine required power increases in response to a reacceleration operation, set the rotational speed and the torque so as to reach a power of the engine to the target engine required power while holding the rotational speed equal to or higher than the rotational speed at a time of the reacceleration operation. The ECU is configured to control the engine operating point based on the set rotational speed and the set torque.

Abstract: The control apparatus of the present invention is applied to a hybrid vehicle that, as power sources for propulsion, includes an internal combustion engine that can change over between lean combustion and stoichiometric combustion, and motor-generators. The control apparatus performs the noise suppression control in which the operating points of the internal combustion engine are limited so as to suppress noise generated by a power transmission mechanism, and changes over the operational mode of the internal combustion engine if the thermal efficiency when performing the noise suppression control by changing over the operational mode of the internal combustion engine is higher than the thermal efficiency when performing the noise suppression control by keeping the operational mode of the internal combustion engine the same.

Abstract: The control apparatus of the present invention is applied to a hybrid vehicle including an internal combustion engine that is capable of changing over its combustion state between lean combustion and stoichiometric combustion. The control apparatus executes noise suppression control by limiting the operating point of the internal combustion engine to be upon a noise suppression line for lean combustion or to be upon a noise suppression line for stoichiometric combustion, so that the noise generated by a power transmission mechanism is suppressed. When changing over from lean combustion to stoichiometric combustion during execution of noise suppression control, the control apparatus of the present invention changes the air/fuel ratio after changing the operating point of the internal combustion engine from one point to a point that is more toward the lower torque side of the noise suppression line.

Abstract: The control apparatus of the present invention is applied to a hybrid vehicle having an internal combustion engine that is capable, during operation, of changing over its operational mode to lean combustion or to stoichiometric combustion. The control apparatus preferentially selects an operational mode having high system efficiency in relation to the requested power, and selects the stoichiometric combustion mode (S104) when, under the specific condition that the system efficiency is higher in the lean combustion mode as compared to the EV mode and moreover is lower in the stoichiometric combustion mode as compared to the EV mode, also the temperature (Tnc) of an exhaust purification catalyst is less than or equal to a first predetermined value (T?) (S101, S102).

Abstract: A hydraulic control system includes a first oil passage, a first oil pump, a second oil passage, a second oil pump and a check valve. The first oil pump is disposed in the first oil passage. The second oil passage bypasses the first oil pump, includes an intake oil passage and a discharge oil passage, the intake oil passage and the first oil passage are connected to each other at a connection point, and the discharge oil passage includes an air vent hole. The second oil pump is disposed in the second oil passage, configured to take in oil from the intake passage, and configured to discharge the oil into the discharge oil passage. The check valve is provided between the connection point and the air vent hole, configured to restrict flow of the oil from the air vent hole toward the connection point via the second oil pump.

Abstract: A vehicle parking lock device stopping rotation of a parking gear formed on a rotating member coupled to drive wheels to stop rotation thereof, including: a parking pole having a claw portion for engagement with the parking gear, the parking pole being rotatable around a support shaft by pushing out a cam movable in an axial direction of the parking gear, the support shaft being in parallel with the axial direction; a stopper plate contacting the parking pole to regulate movement in the axial direction; and a spring contacting the parking pole to bias it in a direction of release of engagement between the claw portion and parking gear, the vehicle parking lock device being configured to dispose a contact point of the contact between the spring and parking pole closer to the stopper plate in the axial direction than a contact point between the parking pole and cam.

Abstract: To provide a dental alginate impression material composition capable of solving a problem that the permeation rate of water with respect to the whole powder of an alginate impression material is slow at the time of use so that a kneading time is long and a sufficient operational time cannot be secured, and a problem that a kneaded material drops into a throat due to aging of the material at the time of taking an impression, the dental alginate impression material composition comprises 0.001 to 1% by weight of one or more kinds selected from oils mainly consisting of a fatty acid and an ester of alcohol, waxes mainly consisting of a fatty acid and an ester of glycerin, and a fatty acid ester; 0.01 to 10% by weight of a surfactant; and 0.01 to 10% by weight of one or more kinds of specific polysaccharides.

Abstract: To provide a dental alginate impression material composition capable of solving a problem that the permeation rate of water with respect to the whole powder of an alginate impression material is slow at the time of use so that a kneading time is long and a sufficient operational time cannot be secured, and a problem that a kneaded material drops into a throat due to aging of the material at the time of taking an impression, the dental alginate impression material composition comprises 0.001 to 1% by weight of one or more kinds selected from oils mainly consisting of a fatty acid and an ester of alcohol, waxes mainly consisting of a fatty acid and an ester of glycerin, and a fatty acid ester; 0.01 to 10% by weight of a surfactant; and 0.01 to 10% by weight of one or more kinds of specific polysaccharides.