An improved selective power assist device includes a controller for controlling a motor selectively coupled to the door and a clutch interposed between a drive shaft and a motor shaft, each having an angular velocity, whereby the motor is operatively coupled with and decoupled from the door. A brake assembly is disposed to synchronize the angular velocities of the drive shaft and the motor shaft allowing the clutch to operatively couple the motor with the door.

Systems and apparatuses include a cab floor defining a center plane, a seat slide actuator coupled to the cab floor and selectively moveable in a direction transverse to the center plane relative to the cab floor, and a seat supported by the seat slide actuator and moveable therewith.

A pump system for a motor vehicle having a first pump and a second pump which can be driven by an electric motor and/or an internal combustion engine, wherein the first pump and the second pump can be coupled by a clutch. A method of operating a pump system in a motor vehicle includes driving a first pump and a second pump by an electric motor and/or an internal combustion engine by coupling the first pump and a second pump.

Methods and systems are provided for a park lock system for an automatic transmission. In one example, a park lock system may include a slideable element coupled to a park rod, a lock slot formed by the slideable element, a cam coupled to an end of a shaft, the shaft positioned within a solenoid and moveable by energization of the solenoid, and a pivotable pawl adapted to couple with the lock slot. In one example, the pivotable pawl is coupled to the lock slot by energization of the solenoid, and a position of the slideable element is locked.

A driving force control method is provided for engine clutch slipping of a TMED HEV that includes an engine 10 and a second motor 50, a first motor 30 disposed at a transmission side, an engine clutch 20 interposed between the engine 10 and the first motor 30, and a multi-clutch transmission 35 connected with an output terminal of the first motor 30. The method includes verifying whether a control for maintaining a target speed of the engine is achieved by an engine feedback control or by a second motor torque feedback control and applying clutch pressure for the clutch slipping with hydraulic pressure. When the clutch pressure is applied clutch slipping transmission torque is estimated. Torque of the engine clutch is equivalent to the pressure as a load. Second motor dischargeable limit torque, second motor assist torque, and engine torque are calculated to then execute a slip control.

A method for calibrating engine clutch delivery torque of a hybrid vehicle includes: determining an engagement control amount of an engine clutch which connects an engine with a driving motor or disconnects the engine from the driving motor based on a difference between speeds of the engine and the driving motor; determining a current delivery torque corresponding to the engagement control amount of the engine clutch that controls the engine clutch to be in a lock-up state and a temperature of the engine clutch; extracting a previous delivery torque that corresponds to the engagement control amount that controls the engine clutch to be in the lock-up state and the temperature and is included in a map table; and applying a weighted value to each of the extracted previous delivery torque and the determined current delivery torque to calibrate the delivery torque included in the map table.

The invention relates to a method for determining an engagement point of a hybrid clutch in a hybrid vehicle; which hybrid clutch is actuated by a hydrostatic clutch actuator and disconnects or connects an internal combustion engine and an electric traction drive; the engagement point is determined by slowly actuating the clutch starting from a position in which the hybrid clutch is in the non-actuated state, and monitoring a moment of the electric traction drive when a defined increase in the momentum is detected. In a method in which engagement point adaptation is optimized, a current engagement point (tp) is adapted during operation of the hybrid vehicle using a start-up routine, by which a first engagement point is determined when the hybrid vehicle is started; the hybrid clutch is moved close to a previously determined engagement point, and starting from said last determined engagement point, the hybrid clutch is displaced further until the defined increase in the moment is detected.

A drive device includes a first drive unit and a second drive unit. A transmission unit includes a primary shaft for connection to the first drive unit, a secondary shaft, and at least one gear pair via which the primary and secondary shafts are operatively connectable to one another. Mounted in coaxial relationship to the secondary shaft is a driving gear which is operatively connected to the second drive unit, and mounted in coaxial relationship to the primary shaft is an output gear which meshes with the driving gear. A secondary-shaft coupling device can couple the driving gear directly with the secondary shaft, and a primary-shaft coupling device can couple the output gear directly with the primary shaft.

The decelerating device according to the disclosure includes first and second planetary gear mechanisms arranged in an inner space of a hollow type electric motor having an annular rotor. The first planetary gear mechanism includes a first ring gear integral with the rotor, a non-rotatable first carrier for supporting a first pinion gear engaged with the first ring gear to be rotatable, and a first sun gear engaged with the first pinion gear. The second planetary gear mechanism includes a second ring gear integral with the rotor, a second carrier supporting a second pinion gear engaged with the second ring gear to be rotatable and connected to the output shaft, and a second sun gear engaged with the second pinion gear and connected to the first sun gear.

A vehicle includes an engine, a transmission mechanism, and an electronic control unit. The electronic control unit performs first switching control when there is a request for switching from a low mode to a high mode. The first switching control is to release a first engagement mechanism, and switch a second engagement mechanism to an engaged state when a difference between input and output rotational speeds of the second engagement mechanism becomes equal to or smaller than a permissible value.