A vehicle drive apparatus that includes an engagement device, a rotating electrical machine, and a frictional engagement device on a power transfer path connecting an input drivably coupled to an internal combustion engine and an output drivably coupled to a wheel, wherein: a cooling oil passage provided in an area where the engagement device is arranged and configured such that oil for cooling the rotating electrical machine passes through the cooling oil passage and an inflow suppression provided between the engagement device and the frictional engagement device and configured to suppress occurrence of a situation in which oil passing through the frictional engagement device flows into the cooling oil passage are provided inside the tube.

A system and method are provided for hybrid electric internal combustion engine applications in which a motor-generator, a switchable coupling and a torque transfer unit are arranged co-axially-arranged with the front end of the engine crankshaft in the constrained environment in front of an engine in applications such as commercial vehicles, off-road vehicles and stationary engine installations. The motor-generator is preferably laterally offset from the switchable coupling. The switchable coupling is an integrated unit in which a crankshaft vibration damper, an engine accessory drive pulley and a clutch overlap with an axial depth nearly the same as a conventional belt drive pulley and engine damper. The system includes an electrical energy store that receives energy generated by the motor-generator when the coupling is engaged. When the coupling is disengaged, the motor-generator may drive the pulley portion of the clutch-pulley-damper to drive engine accessories using energy returned from the energy store.

A triple clutch arrangement and a powertrain for a motor vehicle with a dual clutch transmission for use between at least two drive devices and the dual clutch transmission. A first clutch and a second clutch of the triple clutch arrangement are connectable to the first drive device and in each instance to a transmission input shaft. The first drive device and the second drive device are both connected to, or connectable to, a primary side of the first clutch and/or the second clutch via the third clutch.

A power transmission device is provided, which includes a main-drive-wheel drive part, and an auxiliary-drive-wheel drive part having a power extraction part which has a transfer gear set comprised of a transfer drive gear connected to the main-drive-wheel drive part and a transfer driven gear meshing with the transfer drive gear and configured to transmit power to the auxiliary drive wheels. In a power transmission path from the main-drive-wheel drive part to the transfer drive gear, an input shaft connected to the main-drive-wheel drive part and a power transmission shaft connected to the transfer drive gear are coupled to each other in a radial direction through a first spline having a first backlash. A first shear damper without backlash and a second shear damper provided with a second spline having a second backlash smaller than the first backlash are provided between the input shaft and the power transmission shaft.

A torque transmission arrangement, particularly for an arrangement with an electric machine in a drive module of a hybrid vehicle or electric vehicle, for transmitting a torque from an output shaft, particularly a motor output shaft, to a drive shaft, particularly a transmission input shaft. The drive shaft further has at least one fluid guide channel in which a fluid can be guided in direction of the output shaft. A fluid-carrying element which guides fluid out of the fluid guide channel of the drive shaft into a radially outer region of the output shaft and is provided at the output shaft.

A system for use in an automatic transmission includes a 3-way solenoid-actuated valve includes a valve body having an inlet port and a first outlet port and a second outlet port, a valve disposed within the valve body and slidably controllable to proportion flow between the first outlet port and the second outlet port, and a spring disposed in the valve body to bias the valve for flow toward the second outlet port. The system also includes at least one pump providing fluid to the inlet port, a first fluid circuit connected to the first outlet port providing fluid to a first subsystem of the automatic transmission, and a second fluid circuit connected to the second outlet port providing fluid to a second subsystem of the automatic transmission.

A driving force distribution apparatus includes a hollow shaft configured to rotate together with a ring gear, a first output shaft having a shaft portion inserted through the hollow shaft, a second output shaft arranged coaxially with the first output shaft, and a driving force transmission mechanism configured such that a driving force transmitted to the hollow shaft is transmitted to the first and second output shafts. A case member has a lubricating oil introduction chamber into which lubricating oil stirred up by the ring gear is introduced. The lubricating oil is supplied from the lubricating oil introduction chamber to the driving force transmission mechanism via a space between the hollow shaft and the shaft portion of the first output shaft. The lubricating oil introduction chamber is formed between the hollow shaft and a bearing mechanism that supports one end of the first output shaft.

According to one embodiment, for example, a transfer control device controls a transfer that adjusts torque distribution to front wheels and rear wheels of a four-wheel vehicle and that includes a wet type multi-disc clutch and a piston. The transfer control device includes: a detector that detects, based on an output value of a sensor provided in the vehicle, whether a predetermined condition corresponding to a state immediately before ignition of the vehicle is turned ON is established; a controller that starts moving the piston when the detector detects that the predetermined condition is established, so that the multi-disc clutch is switched to a connected state from a disconnected state; and a storage that stores therein, while the piston is moved by the controller, information on a connection start state at which connection of the multi-disc clutch is started.

A wet multi-plate clutch includes: a piston movable between a transmission position where the piston pushes a clutch plate group including a plurality of inside clutch plates supported on an inside cylinder and a plurality of outside clutch plates supported on an outside cylinder, in an axial direction to cause friction between the inside and outside clutch plates, and a disconnection position where the piston is spaced apart from the clutch plate group; and a movable wall configured to move integrally with the piston. The disconnection position includes a first disconnection position and a second disconnection position where the distance between the clutch plate group and the piston is longer than at the first disconnection position. When the piston is positioned at the first disconnection position, a first through hole provided in the inside cylinder and a second through hole provided in the movable wall overlap in the radial direction.

A power transfer assembly for a motor vehicle includes a clutch protection system to prevent damage to an actively-controlled multi-plate mode clutch of the power transfer assembly. The clutch protection system includes a transfer case control module (TCCM) and an engine control module (ECM) configured to regulate the distribution of torque applied from an engine to front and rear output shafts of the power transfer assembly. The TCCM is in operable communication with the engine control module ECM, wherein TCCM is configured to detect slip in the actively-controlled multi-plate friction clutch and to communicate with the ECM to selectively reduce the output torque of the engine in response to detected slip.