Abstract: A controller of an engine with a supercharger includes, for each of cylinders, fuel supply system and an ignition plug. The controller includes an electronic control unit that is configured to: (i) set a basic ignition timing depending on an operation state of the engine, (ii) detect, for each cycle, an abnormal combustion generation cylinder in which an abnormal combustion is generated in a supercharged region, (iii) execute a fuel cut to stop a fuel supply by the fuel supply system for the abnormal combustion generation cylinder, (iv) change an ignition timing of the abnormal combustion generation cylinder to expand a crank angle width between a compression top dead center and the basic ignition timing for several cycles after start of the fuel cut, and (v) execute an ignition cut that prohibits a spark from being generated by the ignition plug, further after elapse of the several cycles is executed.

Abstract: A controller of an engine with a supercharger includes, for each of cylinders, fuel supply system and an ignition plug. The controller includes an electronic control unit that is configured to: (i) set a basic ignition timing depending on an operation state of the engine, (ii) detect, for each cycle, an abnormal combustion generation cylinder in which an abnormal combustion is generated in a supercharged region, (iii) execute a fuel cut to stop a fuel supply by the fuel supply system for the abnormal combustion generation cylinder, (iv) change an ignition timing of the abnormal combustion generation cylinder to expand a crank angle width between a compression top dead center and the basic ignition timing for several cycles after start of the fuel cut, and (v) execute an ignition cut that prohibits a spark from being generated by the ignition plug, further after elapse of the several cycles is executed.

Abstract: An air-fuel ratio control apparatus includes a catalytic converter disposed at a position downstream of an exhaust gas aggregated portion; a downstream air-fuel ratio sensor disposed in an exhaust passage at a position downstream of the catalytic converter; first feedback amount updating means for updating a first feedback amount to have an output value of the downstream air-fuel ratio sensor coincide with a target downstream-side air-fuel ratio based on the output value of the downstream air-fuel ratio sensor; and a learning means for updating a leaning value of the first feedback amount in such a manner that the leaning value brings in a steady-state component of the first feedback amount based on the first feedback amount.

Abstract: A fuel injection control system of an internal combustion engine includes a required injection setting mechanism, a rapid rotational speed change detector, and an injection controller. The required injection setting mechanism calculates a required number of injections and required injection times with regard to a plurality of fuel injections, based on operating conditions of the engine. The rapid rotational speed change detector determines whether the amount of change of the engine speed is equal to or larger than a predetermined value. When it is determined that the amount of change of the engine speed is equal to or larger than the predetermined value, the injection controller controls a fuel injection valve so as to reduce or eliminate differences between the actual injection times and the required injection times. Thereby, even when the engine speed changes rapidly, deteriorations in the driveability and exhaust emissions are prevented.

Abstract: An internal combustion engine control apparatus includes: a purge control unit causing fuel evaporative emission to be introduced into an intake passage to attain a purge flow rate based on a pressure in the intake passage; a fuel cut return rich control unit setting a rich target air-fuel ratio when returning from fuel cut, and feedback-controlling a fuel supply rate on the basis of the target air-fuel ratio, purge flow rate and intake air flow rate to attain the target air-fuel ratio; a fuel increase upper limit setting unit setting an allowable upper limit for an increase in fuel supply rate in fuel cut return rich control; and an actual air-fuel ratio control unit controlling an actual air-fuel ratio to a richer side when the fuel supply rate in the fuel cut return rich control has reached the allowable upper limit and the actual air-fuel ratio is lean.

Abstract: An internal combustion engine wherein three-way catalysts are arranged in an exhaust passage of a first cylinder group and an exhaust passage of a second cylinder group and a common NOx storage catalyst is arranged downstream of the three-way catalysts. When the NOx storage catalyst should be raised in temperature, the air-fuel ratio of a part of the cylinders in each cylinder group is made rich and the air-fuel ratio of a part of the cylinders in each cylinder group is made lean to raise the NOx storage catalyst in temperature by the heat of oxidation reaction at the three-way catalysts.

Abstract: An exhaust gas control apparatus applied to an internal combustion engine including plural cylinders and a turbocharger, wherein an exhaust passage includes first and second branch passages. The first branch passage connects exhaust sides of cylinders #1, #4 and a turbine, and includes a starter catalyst; the second branch passage connects exhaust sides of cylinders #2, #3 and the turbine, and communicates with the first branch passage upstream of the starter catalyst. The exhaust gas control apparatus includes an exhaust gas switching valve disposed at a communication part, through which the first and second branch passages are in communication, and is switchable between an introducing position at which exhaust gas is introduced into the starter catalyst from the cylinders #2, #3 and a block position at which introduction thereof is blocked. An ECU switches the exhaust gas switching valve position based on the operating condition of the internal combustion engine.

Abstract: An internal combustion engine wherein exhaust gas from the cylinder groups (1, 2) is supplied to a common NOx storage catalyst (12). When the NOx storage catalyst (12) should release the SOx, the average air-fuel ratio of one cylinder group (1) is made rich and the average air-fuel ratio of the other cylinder group (2) is made lean. At this time, the air-fuel ratios of the cylinders (3) of one cylinder group (1) are made one target rich air-fuel ratio selected from two predetermined target rich air-fuel ratios, while the air-fuel ratios of the cylinders (3) of the other cylinder group (2) are made one target lean air-fuel ratio selected from two predetermined target lean air-fuel ratios.

Abstract: A control apparatus includes a detection unit that detects a stop request to an engine, a throttle closing control unit that, when the stop request is detected, adjusts an opening amount of a throttle valve to an engine-stop throttle valve opening amount smaller than a current opening amount an engine stop detection unit that detects a stop of the engine, an engine-stop exhaust valve control unit that adjusts an opening/closing characteristic of an exhaust valve of a cylinder that will be placed initially in an intake stroke when the engine is restarted so that, when the opening amount of the throttle valve is adjusted to the engine-stop throttle valve opening amount and a stop of the engine is detected, the exhaust valve has an engine-stop exhaust valve opening/closing characteristic by which a closing timing of the exhaust valve is more delayed than a current closing timing of the exhaust valve.

Abstract: An air-fuel ratio control apparatus includes a catalytic converter disposed at a position downstream of an exhaust gas aggregated portion; a downstream air-fuel ratio sensor disposed in an exhaust passage at a position downstream of the catalytic converter; first feedback amount updating means for updating a first feedback amount to have an output value of the downstream air-fuel ratio sensor coincide with a target downstream-side air-fuel ratio based on the output value of the downstream air-fuel ratio sensor; and a learning means for updating a leaning value of the first feedback amount in such a manner that the leaning value brings in a steady-state component of the first feedback amount based on the first feedback amount.

Abstract: According to the invention, an exhaust gas purification device for an engine is provided. The device comprises: a plurality of cylinders, the cylinders being divided into at least two cylinder groups; exhaust branch pipes connected to the cylinder groups at their upstream ends, respectively; a common exhaust pipe connected to the downstream ends of the exhaust branch pipes; and a NOx catalyst positioned in the common exhaust pipe.

Abstract: In an exhaust purification system that purifies exhaust from a plurality of cylinder groups of an internal combustion engine, an exhaust passageway (1,51) from each cylinder group is divided into a plurality of passageways (2a, 2b, 52a, 52b/3,53). With regard to one or more of the divided exhaust passageways (3,53), the amount of exhaust passing therethrough is reduced so as to reduce the heat release to the outside from the exhaust as a whole. In this manner, the temperature of exhaust introduced into an exhaust purification device (4,54) is kept at high temperature.

Abstract: An internal combustion engine including an in-cylinder injection injector and an intake port-injection injector. An ECU includes a fuel injection duration calculation portion that calculates a requested fuel injection duration and a fuel injection control portion that causes the in-cylinder injection injector to inject fuel during the compression stroke during the cold start of the engine, and that causes fuel to be injected also in a manner other than the fuel injection performed by the in-cylinder injection injector during the compression stroke if the requested fuel injection duration is longer than or equal to an interval time. Therefore, even if the requested fuel injection duration is longer than or equal to the interval time, the emissions can be reduced while a startability during a cold start of the internal combustion engine is secured.

Abstract: A fuel injection control system of an internal combustion engine includes a required injection setting mechanism, a rapid rotational speed change detector, and an injection controller. The required injection setting mechanism calculates a required number of injections and required injection times with regard to a plurality of fuel injections, based on operating conditions of the engine. The rapid rotational speed change detector determines whether the amount of change of the engine speed is equal to or larger than a predetermined value. When it is determined that the amount of change of the engine speed is equal to or larger than the predetermined value, the injection controller controls a fuel injection valve so as to reduce or eliminate differences between the actual injection times and the required injection times. Thereby, even when the engine speed changes rapidly, deteriorations in the driveability and exhaust emissions are prevented.

Abstract: An internal combustion engine wherein exhaust gas from the cylinder groups (1, 2) is supplied to a common NOx storage catalyst (12). When the NOx storage catalyst (12) should release the SOx, the average air-fuel ratio of one cylinder group (1) is made rich and the average air-fuel ratio of the other cylinder group (2) is made lean. At this time, the air-fuel ratios of the cylinders (3) of one cylinder group (1) are made one target rich air-fuel ratio selected from two predetermined target rich air-fuel ratios, while the air-fuel ratios of the cylinders (3) of the other cylinder group (2) are made one target lean air-fuel ratio selected from two predetermined target lean air-fuel ratios.

Abstract: An internal combustion engine wherein three-way catalysts are arranged in an exhaust passage of a first cylinder group and an exhaust passage of a second cylinder group and a common NOx storage catalyst is arranged downstream of the three-way catalysts. When the NOx storage catalyst should be raised in temperature, the air-fuel ratio of a part of the cylinders in each cylinder group is made rich and the air-fuel ratio of a part of the cylinders in each cylinder group is made lean to raise the NOx storage catalyst in temperature by the heat of oxidation reaction at the three-way catalysts.

Abstract: An exhaust gas control apparatus applied to an internal combustion engine including plural cylinders and a turbocharger, wherein an exhaust passage includes first and second branch passages. The first branch passage connects exhaust sides of cylinders #1, #4 and a turbine, and includes a starter catalyst; the second branch passage connects exhaust sides of cylinders #2, #3 and the turbine, and communicates with the first branch passage upstream of the starter catalyst. The exhaust gas control apparatus includes an exhaust gas switching valve disposed at a communication part, through which the first and second branch passages are in communication, and is switchable between an introducing position at which exhaust gas is introduced into the starter catalyst from the cylinders #2, #3 and a block position at which introduction thereof is blocked. An ECU switches the exhaust gas switching valve position based on the operating condition of the internal combustion engine.

Abstract: A control apparatus includes a detection unit that detects a stop request to an engine, a throttle closing control unit that, when the stop request is detected, adjusts an opening amount of a throttle valve to an engine-stop throttle valve opening amount smaller than a current opening amount an engine stop detection unit that detects a stop of the engine, an engine-stop exhaust valve control unit that adjusts an opening/closing characteristic of an exhaust valve of a cylinder that will be placed initially in an intake stroke when the engine is restarted so that, when the opening amount of the throttle valve is adjusted to the engine-stop throttle valve opening amount and a stop of the engine is detected, the exhaust valve has an engine-stop exhaust valve opening/closing characteristic by which a closing timing of the exhaust valve is more delayed than a current closing timing of the exhaust valve.

Abstract: An internal combustion engine control apparatus includes: a purge control unit causing fuel evaporative emission to be introduced into an intake passage to attain a purge flow rate based on a pressure in the intake passage; a fuel cut return rich control unit setting a rich target air-fuel ratio when returning from fuel cut, and feedback-controlling a fuel supply rate on the basis of the target air-fuel ratio, purge flow rate and intake air flow rate to attain the target air-fuel ratio; a fuel increase upper limit setting unit setting an allowable upper limit for an increase in fuel supply rate in fuel cut return rich control; and an actual air-fuel ratio control unit controlling an actual air-fuel ratio to a richer side when the fuel supply rate in the fuel cut return rich control has reached the allowable upper limit and the actual air-fuel ratio is lean.

Abstract: There is provided an air supply apparatus for an engine comprising a plurality of exhaust pipes and catalysts arranged in the exhaust pipes, respectively, the apparatus comprising devices for supplying air into the interior of the corresponding exhaust pipes upstream of the corresponding catalysts, respectively.