A control apparatus for a vehicle that is provided with (i) an engine, (ii) a first starting device including an electric motor and a high-voltage power supply device, such that the first starting device cranks the engine by using the electric motor, (iii) a second starting device including a starter motor and a low-voltage power supply device, such that the second starting device cranks the engine by using the starter motor, and (iv) various kinds of electrical equipment operable by an electric power supplied from the low-voltage power supply device. In a case in which start of the engine by cranking the engine by using the first starting device has failed and then the start of the engine by cranking the engine by using the second starting device has failed, the control apparatus cranks the engine by using the second starting device again.

An ignition system for outdoor power equipment driven by a petrol or gasoline engine may include a safety interlock system, a starter motor, a starter solenoid having an activation coil, and a solenoid monitor. The ignition system may be configured to selectively apply power to start the engine based on application of a start attempt. The safety interlock system may be operable to actuate the starter solenoid via the activation coil to apply current to the starter motor for starting the engine during the start attempt. The solenoid monitor may be configured to determine a status of the activation coil and starter solenoid contacts and provide a fault indication based on the status determined.

A method of starting an integrated starter generator drives a starter generator without using a rotor position sensor to start an engine. The method includes the following steps of: (a) applying a first drive current with a first frequency and a first amplitude to drive the starter generator to reversely rotate in a speed open-loop control mode, and acquiring a first load information according to a drive voltage and the first drive current of the starter generator, (b) confirming whether the first load information meets a heavy load condition, (c) stopping reversely rotating the starter generator when the first load information meets the heavy load condition, and (d) forwardly rotating the starter generator to drive the engine to start.

A DC power plant generating DC power from a variety of engines including a Stirling cycle engine. The DC power plant includes a relatively small start-up power source that is discontinued after the engine is running. A method for producing DC power for a load including starting up an engine using power supplied by a relatively small power supply supplemented by a capacitor bank, providing output from the engine to a generator, producing alternating current (AC) power by the generator, converting the AC power to direct current (DC) power, disabling output of the DC power during a first set of pre-selected conditions, limiting a rate of change of current of the DC power during a second set of pre-selected conditions, reducing conducted and radiated emissions of the DC power, disconnecting the DC power from the load under a third set of pre-selected conditions, and providing the DC power to the load.

An acceleration method for a hybrid drivetrain includes providing the hybrid drivetrain, setting an initial torque transmission ratio of a belt-drive transmission to a lower transmission ratio, and opening a first disconnect clutch to interrupt torque transmission between an internal combustion engine and an electric machine. The method also includes receiving an acceleration command, shifting the torque transmission ratio with a transmission adjustment gradient from the lower transmission ratio towards an upper transmission ratio, increasing a rotor speed of a rotor shaft of the electric machine with a rotor shaft adjustment gradient, and engaging a first disconnect clutch to rotate an ICE shaft to start the internal combustion engine and increase a rotational speed of the ICE shaft towards a current rotor speed.

A start control device for a hybrid vehicle includes a battery, first and second rotary electric machines, an engine, a first determination unit configured to determine whether the battery is in a low output state, a cranking control unit configured to perform a cracking of the engine, and a second determination unit configured to perform a cranking completion determination. In a case where a maximum output of the battery is in the low output state, the cranking control unit causes the first rotary electric machine to run at a low output target rotation speed, and the second determination unit determines that the cranking is completed when a condition that an actual rotation speed of the first rotary electric machine continues to be within a target range for a predetermined time is satisfied.

An enhanced automotive electrical battery system having a primary automobile electrical energy source of an automobile having a combustion engine, a receiver configured to receive one or more wireless signals to respectively control one or more automobile functions, and a remote keyless entry (RKE) having a transmitter in wireless communication with the receiver and having one or more buttons. The remote keyless entry (RKE) is configured in an operating mode to transmit, via the transmitter, the one or more wireless signals to the receiver upon activation by the respective one or more buttons. Upon receipt of the one or more wireless signals by the receiver, one or more automobile functions are controlled without starting the combustion engine of the automobile.

An ignition system for outdoor power equipment driven by a petrol or gasoline engine may include a safety interlock system, a starter motor, a starter solenoid having an activation coil, and a solenoid monitor. The ignition system may be configured to selectively apply power to start the engine based on application of a start attempt. The safety interlock system may be operable to actuate the starter solenoid via the activation coil to apply current to the starter motor for starting the engine during the start attempt. The solenoid monitor may be configured to determine a status of the activation coil and starter solenoid contacts and provide a fault indication based on the status determined.

A method and system for controlling a stop rotation position of an engine is described. In one example, the system includes an integrated starter/generator that may be selectively coupled to the engine. The integrated starter/generator may rotate the engine in a first direction (e.g., reverse direction) or a second direction (e.g., a forward direction) in response to a position at which the engine stops rotating following cessation of combustion in the engine.

A method and system for controlling a stop rotation position of an engine is described. In one example, the system includes an integrated starter/generator that may be selectively coupled to the engine. The integrated starter/generator may rotate the engine in a first direction (e.g., reverse direction) or a second direction (e.g., a forward direction) in response to a position at which the engine stops rotating following cessation of combustion in the engine.