An engine accessory drive (EAD) system for an engine includes a motor-generator (MGU) unit operably coupled to an accessory. The EAD system also includes a gearbox assembly, which includes a first gear train operably coupled to the MGU, and a second gear train operably coupled to an output of the engine. The gearbox assembly also includes a clutch selectively coupling the first gear train with a second gear train. The EAD system further includes a starter assembly, which includes a starter shaft operably coupled to the second gear train. The starter assembly also includes a starter pinion coupled to the starter shaft, and an actuator configured to selectively engage the starter pinion with a flywheel of the engine. Further yet, the EAD system includes an EAD controller configured to selectively operate the EAD system in one of a generator mode, an accessory drive mode, and a starter mode.

A starter has a high voltage direct current electric motor, a speed reduction device, a clutch, an output gear and a switch box configured to turn on the electric motor. The output gear is driven by the electric motor via the speed reduction device and the clutch. The starter also has a stationary axle on which the output gear is installed. The electric motor has an output shaft. The speed reduction device has a drive gear fixed to the output shaft and a driven gear meshed with the drive gear, the driven gear being rotatably mounted to the axle via a bushing.

The engine starter includes a pinion-mobile component which is linked to an output shaft by a helical spline and can be slid in a shaft direction, in a state where the pinion-mobile component includes; an overrunning clutch which is idled when the pinion gear, which is engaged to the ring gear, is driven by the engine via the ring gear so as to be rotated at a rotational speed which is higher than a rotational speed of the output shaft; and a breaking mechanism in which the overrunning clutch breaks a transmission of a torque, which is generated in accordance with a rotation of the motor and is transmitted to the ring gear, when a value of the torque is a predetermined condition value with respect to a direction where the torque is transmitted to the ring gear.

A starter assembly including a starter and starting device. The starter includes: an electric motor including a motor shaft; an output shaft non-rotatably connected to the motor shaft; and a one-way clutch including a first race including an axially fixed pinion gear and a second race non-rotatably connected to the output shaft. The starting device includes a wrap spring clutch with first and second ends. For a start mode: the electric motor rotates the motor shaft and the pinion gear in a first circumferential direction; the pinion gear rotates the second end, with respect to the first end, in the first circumferential direction; and, the wrap spring clutch rotates a torque converter shell in the first circumferential direction. For a first phase of a release mode: the electric motor rotates the second race in a second circumferential direction; and the first race rotates in the second circumferential direction.

Methods and systems are provided for starting a vehicle engine. In one example, an engine starter system for starting the vehicle engine may comprise a ring gear coupled to an engine crankshaft, and a pinion gear coupled to a starter motor, the pinion gear having rotatable rocker elements for engaging the ring gear. In this way, the pinion gear may be engaged with the ring gear to transmit torque from the starter motor to the engine crankshaft to quickly start the engine.

The invention includes a stator disposed inside a yoke, an armature supported inside the stator, a commutator connected to the armature and having a sliding surface in an outer peripheral portion, and a brush disposed opposing the commutator and having a sliding contact surface that comes into sliding contact with the sliding surface of the commutator, wherein the brush has a first member, and a second member with an electrical resistance value higher than that of the first member, the first member is disposed on an entrance side and the second member on an exit side with respect to a direction of rotation of the commutator, and the sliding contact surface of the brush is such that an inclined portion that inclines toward the entrance side with respect to the direction of rotation of the commutator is formed in the first member.

A starter-generator system may include a starter-generator configured to provide an engine-cranking torque or receive a generator-cranking torque, a belt drive mechanism located between the starter-generator and an engine, and a torque transmission mechanism that selectively transmits the engine-cranking torque or the generator-cranking torque between the starter-generator and the belt drive mechanism.

The various implementations described herein include apparatuses and methods used to operate engine-based equipment using an electric starter motor. In one aspect, a method for operating an apparatus includes starting an electric starter motor. In response to starting the electric starter motor, the electric starter motor is coupled to a flywheel and the flywheel is turned. In response to turning the flywheel, an engine coupled to the flywheel via a power take-off of the engine is started. After starting the engine, the electric starter motor is decoupled from the flywheel and thus from the engine, and the engine is used to turn the flywheel, thereby enabling operation of a primary assembly coupled to the flywheel.

An internal combustion engine includes an engine block including a cylinder, a piston positioned within the cylinder, a crankshaft configured to be driven by the piston, a fuel supply system for supplying an air-fuel mixture to the cylinder, an ignition system, an electric starting system including a starter motor, and an ultracapacitor mounted on the engine, the ultracapacitor configured to power the starter motor to start the engine. A related garden tool is also disclosed.

Provided is a motor generator, which is always connected to an engine via a belt, and is configured to carry out start control of the engine and power generation control, the motor generator having a two-output power transmission mechanism including: a belt driving mechanism, which is configured to drive the engine through the belt; and a gear driving mechanism, which includes a pinion gear to be coupled to a ring gear on the engine side in accordance with an external instruction, and is configured to drive the engine by the pinion gear being coupled to the ring gear, in which an output of the belt driving mechanism and an output of the gear driving mechanism are arranged at positions opposing each other in an axial direction of a rotor of the motor generator.