An exhaust gas heat recovery (EGHR) system for a vehicle is configured to selectively distribute a fluid heated by engine exhaust through a coolant path for heating an engine, a transmission and a battery during cold operating conditions until a desired operating temperature is reached. In response to receiving one or more heating requests from the engine, transmission and/or battery, a controller distributes the fluid through the coolant path according to a priority level for each heating request received, wherein the priority level for each heating request may be based on current vehicle operating conditions and/or driver demand.

A control system for a hybrid electric vehicle comprises a transmission system configured to drive wheels, an engine power subsystem connected to the transmission system, a motor power subsystem connected to the transmission system and a control module. When vehicle's electrical power is on, the control module is configured to control operating mode of the hybrid electric vehicle through the engine power subsystem and the motor power subsystem. The operating mode comprises HEV-eco mode and HEV-s mode. When the hybrid electric vehicle operates in HEV-eco and the hybrid electric vehicle operates at low power or when the hybrid electric vehicle operates in HEV-s mode and when the vehicle speed is zero, the control module enables the hybrid electric vehicle to operate by idle start-stop strategy.

A control device is provided for controlling a vehicle that includes: an internal combustion engine having a fuel injection valve, an ignition device and an in-cylinder pressure sensor; and an electric motor configured to rotate to drive a crankshaft of the internal combustion engine. The control device is configured, when an assist torque is applied to the crankshaft by means of the electric motor, to perform an ignition start-up operation that starts fuel injection and ignition from an expansion stroke cylinder to start up the internal combustion engine. The assist torque is a torque by which the crankshaft is not caused to rotate, and is greater when an in-cylinder pressure in a compression stroke cylinder is higher.

A control device of the present invention is applied to a hybrid vehicle having an internal combustion engine which is enabled to operate with fuels different in alcohol density from each other. In a case that fueling which causes change of alcohol density of fuel is implemented to the hybrid vehicle, the control device prohibits an intermittent stop of the internal combustion engine until fuel having an alcohol density changed by the fueling is supplied to the internal combustion engine.

A control unit disposed on a vehicle for use in a system for monitoring, configuring, programming and/or diagnosing operation on at least one vehicle system. The control unit comprising a user interface and a network interface to support communication between the control unit and at least one remote device, to perform various functions such as remote start, remote schedule start, vehicle health diagnostics, and tracking on the vehicle remotely.

An electric motor for starting internal combustion engines and a relative starting control system of such engine comprising said electric motor of the type with permanent magnets allows a more effective and simpler management of the internal combustion engine thereto the electric motor is connected, wherein a monitoring unit of the electric motor (EMU) and a monitoring unit of the internal combustion engine (ECU) are provided, wherein the electric motor comprises a direction sensor (18) providing a signal representing the rotation direction of the rotor (12) of the electric motor, which is connected to said monitoring unit of the internal combustion engine (ECU).

An engine control apparatus is used with a system equipped with an engine and an engine starter. The engine starter includes an electrical motor, a pinion gear driven by the electrical motor, and a pinion shifter which thrusts the pinion to a location where the pinion is engageable with a ring gear coupled to the engine. The engine control apparatus determines a pulsation parameter which represents a pulsating component of speed of the engine or a value correlating with the pulsating component. The engine control apparatus works to thrust the pinion through the pinion shifter to establish engagement with the ring gear and then rotate the electrical motor to crank the engine. The engine control apparatus alters a cranking terminating time as a function of the pulsation parameter. This minimizes mechanical noise occurring between the pinion gear and the ring gear at the start of the engine.

A fuel filter element, which may be selectively arranged in a filter housing and may separate in the filter housing an untreated space communicating with an inlet and a return line of the housing from a treated space communicating with an outlet of the housing, may include at least one end disk, and at least one closure element, which in an operationally ready state of the fuel filter may close off the return line. The closure element may protrude eccentrically axially away from the at least one end disk. The closure element may have a seal on a surrounding surface and that, in the operationally ready state, may be in contact with a surface of the return line. In the operationally ready state, a portion of the closure element may be located in a filter chamber of the filter housing and another portion of the closure element may be located in the return line.

A control device for starting an internal combustion engine by outputting torque from an electric motor connected to a torque transmission path from an internal combustion engine to a drive wheel so as to be capable of transmitting torque, wherein a pulsating component of a reaction force torque generated by starting the internal combustion engine is obtained, and a pulsating component of a torque input to the compositing position is obtained on the basis of a spring constant, a damping coefficient, and a moment of inertia of a power transmission member between a compositing position where torque is transmitted from the electric motor to the torque transmission path and the internal combustion engine, and a pulsating component of the reaction force torque, and an AC component torque and a cranking torque are added to determine a torque command value of the electric motor when starting the internal combustion engine.

A fuel filter for a fuel supply system of an internal combustion engine may include a filter housing, which may have an untreated-side inlet, a treated-side outlet, and an untreated-side return line. The fuel filter may also include a filter element arranged in the filter housing, and a closure element, which in an operationally ready state of the fuel filter may close off the return line. The fuel filter may include an untreated space and a treated space, and may separate in the filter housing the untreated space communicating with an inlet and the return line from the treated space communicating with the outlet. The fuel filter may further include a pressure sensor configured to measure a pressure build-up in the treated space, wherein the fuel filter may be configured to enable the pressure build-up to reach a predetermined threshold at which the engine may be started.