An auxiliary machine-driving device has a first idler roller disposed between an engine roller and a first rotating roller; a second idler roller disposed between the first rotating roller and a second rotating roller; a third idler roller disposed between the second rotating roller and the engine roller; and a linking mechanism driven by one actuator to switch the first idler roller between a state in which the first idler roller contacts the engine roller and the first rotating roller, and a state in which the first idler roller separates from the engine roller and the first rotating roller, and to switch at least one of the second and third idler rollers between a state in which the at least one roller contacts two rollers adjacent the at least one roller, and a state in which the at least one roller separates from the two rollers.

An engine-and-electric-machine assembly is provided that includes an engine and an electric machine, a crankshaft being provided in the engine, the crankshaft including a main body and an extension section that extends out to the exterior of the engine, the extension section forming a rotation shaft of the electric machine, and a rotor of the electric machine being mounted on the extension section. Moreover, a terminal of the rotation shaft is connected to a coolant pump, a rotor of the coolant pump is mounted to the rotation shaft, and while the rotation shaft is rotating the rotation shaft drives the coolant pump to provide coolant to the electric machine. By connecting the rotation shaft of the electric machine to the coolant pump, the assembly enables the pump to be highly integrated into the system and reduce manufacturing cost.

Pulley-movement detection within an alternator or integrated starter/generator (ISG) for a vehicle is provided. The alternator or ISG includes a housing, a stator fixed within the housing, a rotor configured to rotate relative to the stator about an axis, and a shaft coupled to the rotor for rotation about the axis. The alternator or ISG also includes pulley coupled to the shaft at an interface, and configured to engage with a chain or belt to transfer movement between the shaft and the chain or belt. An electrical switch located at the interface is configured to be in a first state when the pulley is axially secured to the shaft, and a second state when the pulley is axially displaced away from the shaft. This can enable signals or warnings to be output in response to the electrical switch changing states, indicating an improper connection at the interface.

Methods and systems are provided for a starter/generator in a vehicle drivetrain. In one example, a system may include an integrated starter/generator (ISG) rotationally coupled to an engine crankshaft via a belt drive system, the belt drive system including a first decoupler configured to engage a shaft of the ISG in a first torque transfer direction only and a second decoupler configured to engage the shaft of the ISG in a second torque transfer direction only, the second torque transfer direction opposite the first torque transfer direction. In this way, hubloads that occur while transitioning the ISG between driving the belt drive system and being driven by the belt drive system may be reduced while a response time of the transitioning may also be reduced.

An accessory drive, including a planetary gear set with a plurality of components arranged to be concentrically disposed around a crankshaft of an internal combustion engine. The plurality of components includes: a sun gear; a planet carrier; a ring gear; and a planet gear meshed with the sun gear and the ring gear. A first component of the planetary gear set: is arranged to non-rotatably connect to a rotor of an electric motor/generator; and is arranged to connect to a power transfer component for least one accessory. A second component of the planetary gear set is arranged to non-rotatably connect to the crankshaft. For a starting mode of the accessory drive, the electric motor/generator is arranged to: rotate the first component of the planetary gear set; and rotate the second component of the planetary gear set with respect to the first component of the planetary gear set.

A cooling system for an automotive transmission is provided. The cooling system includes a housing defining a housing inlet. The housing defines an interior space that is in fluid communication with the housing inlet. A propeller assembly has a rotatable shaft and a blade extending from the rotatable shaft, which is configured to draw ambient air into the interior space of the housing through the housing inlet. A propulsion system assembly includes an engine configured to provide propulsion power through an engine output and an automotive transmission configured to receive the propulsion power from the engine output. A clutch is configured to selectively couple the engine output to the automotive transmission. The clutch is disposed in a housing, where the housing defines an ambient air inlet. A rotatable shaft having a blade is configured to draw ambient air into the housing through the ambient air inlet to cool the clutch.

Pulley-movement detection within an alternator or integrated starter/generator (ISG) for a vehicle is provided. The alternator or ISG includes a housing, a stator fixed within the housing, a rotor configured to rotate relative to the stator about an axis, and a shaft coupled to the rotor for rotation about the axis. The alternator or ISG also includes pulley coupled to the shaft at an interface, and configured to engage with a chain or belt to transfer movement between the shaft and the chain or belt. An electrical switch located at the interface is configured to be in a first state when the pulley is axially secured to the shaft, and a second state when the pulley is axially displaced away from the shaft. This can enable signals or warnings to be output in response to the electrical switch changing states, indicating an improper connection at the interface.

A system includes a valve actuation system, a pre-lubrication pump coupled to a lubrication circuit and configured to provide oil to the valve actuation system, a catalyst for receiving and treating exhaust gasses, and a controller. The controller is configured to identify an engine start request and determine whether the catalyst temperature is below a first threshold value. In response to determining that the catalyst temperature is below the first threshold value, the controller actuates the pre-lubrication pump to direct lubricant to the valve actuation system, controls the valve actuation system to deactivate at least one cylinder of an engine, and, subsequent to deactivating the at least one cylinder of the engine, cranks the engine.

A combination starter-generator device includes an electric machine and a gear set configured to couple the electric machine and the engine in first and second power flow directions. The gear set is configured to operate in one of at least a first mode, a second mode, or a third mode in the first power flow direction and at least a fourth mode in the second power flow direction. The starter-generator device includes a clutch arrangement with at least one clutch selectively coupled to the gear set to effect the first, second, and third mode in the first power flow direction and the fourth mode in the second power flow direction; and a cam plate configured to shift the at least one clutch between a disengaged position and an engaged position relative to the gear set.

Methods and systems are provided for extending a duration of engine idle-stop while reducing a frequency of engine restart from idle-stop. In one example, in response to engine restart conditions where combustion torque is not necessary, an engine can be rotated electrically, without fuel delivery, via an electric motor. The unfueled engine spinning via the motor drives an FEAD which in turns drives an actuator coupled to the FEAD, such as an AC compressor or an automatic transmission oil pump.