The present disclosure provides a system for reducing cold start emissions of a motor vehicle. A brushless DC motor is coupled to an engine for cranking the engine. In response to receiving a cold start signal from a cold start actuator, the motor controller activates the brushless DC motor to crank the engine for a cold start duration and increase fuel pressure. In response to a motor controller receiving an auto start signal from an auto start actuator, the motor controller activates the brushless DC motor to crank the engine for an auto start duration that is shorter than the cold start duration. In response to determining that the cold start duration or the auto start duration has expired, an engine controller activates the fuel delivery system to deliver fuel to the engine.

An internal combustion engine comprises at least one cylinder, at least one cylinder head connected to at least one cylinder, at least one piston disposed in the at least one cylinder, a crankshaft operatively connected to the at least one piston, a crankcase housing at least a portion of the crankshaft, a motor-generator operatively connected to the crankshaft, a recoil starter operatively connected to the crankshaft, and a drive pulley of a continuously variable transmission (CVT) operatively connected to the crankshaft, the motor-generator. The recoil starter, the crankshaft and the drive pulley are coaxial. The motor-generator operates in motor mode to rotate the crankshaft and in generator mode to generate electricity.

A method and a system for operating an electric turning machine (ETM) operatively connected to an internal combustion engine (ICE) are disclosed. The ETM operates as a motor with a first control strategy and as a generator with a second control strategy, the second control strategy being distinct from the first control strategy. The system comprises an engine control unit adapted for controlling an operation of the ETM according to the first and second control strategies. Electric and assisted start procedures are available for starting the ICE by delivering electric power from a power source to the ETM which is co-axially mounted to a crankshaft of the ICE. Assisted start includes delivering the electric power to the ETM while a recoil starter is used to rotate the crankshaft. A manual start procedure is also available. The power source is charged by the ETM when the ICE is running.

Systems and methods for operating a spark ignition engine that includes a particulate filter in the engine's exhaust system are described. In one example, a threshold temperature at which the spark ignition engine may be automatically stopped is adjusted according to an amount of soot that is stored in the particulate filter.

In a method for reducing particulate emissions of an internal combustion engine during a cold start of the internal combustion engine, the combustion chamber temperature and the ambient temperature are determined. A cold start condition is recognized when the combustion chamber temperature is below a first threshold temperature and the ambient temperature is below a second threshold temperature. In this case, the internal combustion engine is dragged by means of the starter, wherein air that is present in the combustion chambers is compressed and heated. This heat is discharged to the combustion chamber walls, which are likewise heated up. In this operating situation there is no fuel injection in the combustion chambers and no ignition, so that no combustion takes place in the combustion chambers and the internal combustion engine compresses solely fresh air. The combustion chambers heat up due to the compression work, thus achieving better evaporation of the fuel in the combustion chamber. An initially switched-off fuel injection into the combustion chambers is switched on when the combustion chamber walls of the combustion chambers have reached a sufficient temperature, so that the soot formation due to unburned fuel striking the cold combustion chamber walls is reduced.

A method for operating an electric turning machine (ETM) operatively connected to an internal combustion engine (ICE) are disclosed. An engine control unit (ECU) controls the ETM to operate as a motor with a first control strategy and as a generator with a second control strategy. The second control strategy is distinct from the first control strategy. The ECU controls switching the operation of the ETM from the first control strategy to the second control strategy when a sensor senses that a rotational speed of the ICE is equal to or above a minimum revolution threshold.

An electronic control for engine block heater elements for heating an engine to an engine ready temperature includes a power input, a power output, and a controller. The controller includes a clock for keeping a time and a temperature sensor for sensing a temperature. The controller is configured for controlling the power from the power input to the power output in at least two modes of operation for heating the engine to the engine ready temperature. The second mode of timed ready is where the power from the power input to the power output is connected at a pre-calculated time interval for the purpose of making ready the subject vehicle for starting at the desired start time as set by the user. The third mode of maintain ready is where the power from the electrical outlet to the engine block heater element is regulated to maintain the engine ready temperature.

Systems and methods for managing auto start of a vehicle during an auto-stop condition may include determining an operational status of a vehicle climate control system; receiving a target air outlet temperature from the vehicle climate control system; receiving data indicating a state of a heated seat of the vehicle; and inhibiting a start-vehicle command to restart the vehicle because of a cabin heating requirement when the data indicates that the heated seat of the vehicle is activated.

A control device for an internal combustion engine is configured to: execute a first decompression operating processing such that a decompression operating state is selected in a first engine speed region that passes in the course of engine stop; execute a decompression stop processing such that a switching from the decompression operating state to a decompression stop state is performed in the course of the engine stop after passage of the first engine speed region; when a temperature correlation value is greater than or equal to a threshold value upon an engine start-up request, execute a second decompression operating processing such that the decompression operating state is selected in a second engine speed region that passes in the course of engine start-up before the start of fuel injection. When the temperature correlation value is smaller than the threshold value, the second decompression operating processing is not executed.

Provided are a motor capable of forcibly rotating an engine when the engine is started; and an electric supercharger disposed in an intake passage and driven by electric energy. When the engine is started in a state that a temperature inside a cylinder is equal to or higher than a predetermined first reference temperature, the electric supercharger is driven after an assist motor is driven. When the engine is started in a state that a temperature inside the cylinder is lower than the first reference temperature, the assist motor is driven after the electric supercharger is driven.