A power transmission mechanism includes a first pinion gear meshed with a first sun gear coupled to a first output shaft; a second pinion gear meshed with a second sun gear coupled to a second output shaft and meshed with the first pinion gear; a differential case coupled to an input shaft and supporting the first and second pinion gears; an internal gear rotatable about the axes of the first and second output shafts; a motor generator coupled to the internal gear; a first one-way clutch including a first inner ring member configured to move in conjunction with the first pinion gear and a first outer ring member meshed with the internal gear; and a second one-way clutch including a second inner ring member configured to move in conjunction with the second pinion gear and a second outer ring member meshed with the internal gear.

A power transmission mechanism includes a first pinion gear meshed with a first sun gear coupled to a first output shaft; a second pinion gear meshed with a second sun gear coupled to a second output shaft and meshed with the first pinion gear; a differential case coupled to an input shaft and supporting the first and second pinion gears; an internal gear rotatable about the axes of the first and second output shafts; a motor generator coupled to the internal gear; a first one-way clutch including a first inner ring member configured to move in conjunction with the first pinion gear and a first outer ring member meshed with the internal gear; and a second one-way clutch including a second inner ring member configured to move in conjunction with the second pinion gear and a second outer ring member meshed with the internal gear.

A torque transfer device has plural planets arranged for planetary rotation about one or more sun gears and within one or more ring gears. Each planet includes at least one planetary gear set comprising plural planetary gears connected to rotate together, but having a different diameter to form a differential gear system. To improve load sharing, the plural planetary gears of each planetary gear set may have a different helical angle, the plural planetary gear sets being axially movable with respect to one another. Alternatively or in addition, the planetary gears may be made flexible with respect to radial forces.

A driveline component includes a housing, a first rotating component and a second rotating component, an actuator and a biasing component. The actuator has a body coupled to the first rotating component, the actuator drives the body relative to the second rotating component, and the body is movable between a first position in which the body is not coupled with the second rotating component and a second position in which the body is coupled with the second rotating component. The biasing component has a retainer and a spring, the retainer is in contact with a stop surface that limits movement of the retainer, the spring is fixed to the retainer on one side of the spring and the spring is contacted by the body during at least a portion of the movement of the body to provide a biasing force on the body.

A driveline component includes a housing, a first rotating component and a second rotating component, an actuator and a biasing component. The actuator has a body coupled to the first rotating component, the actuator drives the body relative to the second rotating component, and the body is movable between a first position in which the body is not coupled with the second rotating component and a second position in which the body is coupled with the second rotating component. The biasing component has a retainer and a spring, the retainer is in contact with a stop surface that limits movement of the retainer, the spring is fixed to the retainer on one side of the spring and the spring is contacted by the body during at least a portion of the movement of the body to provide a biasing force on the body.

Methods and systems for an electric drive axle of a vehicle are provided. An electric drive axle system includes, in one example, a gear train configured to rotationally attach to an electric motor-generator. The gear train includes an output shaft rotationally coupled to a first planetary gear assembly axially offset from an input shaft rotationally coupled to the electric motor-generator, the first planetary gear assembly configured to removably couple to a differential arranged co-axial with an axle.

A power transmission device includes a first input shaft configured to input power from a first power source, a second input shaft configured to input power from a second power source, a first output shaft configured to transmit power to a first drive wheel, a second output shaft configured to transmit power to a second drive wheel, and a differential gear including, as three rotation elements, a first rotation element to which the second input shaft is connected, a second rotation element to which the second output shaft is connected, and a third rotation element to which the first input shaft and the first output shaft are connected, in which an engagement device configured to selectively connect any two of the three rotation elements is provided.

A power transmission device includes a first input shaft configured to input power from a first power source, a second input shaft configured to input power from a second power source, a first output shaft configured to transmit power to a first drive wheel, a second output shaft configured to transmit power to a second drive wheel, and a differential gear including, as three rotation elements, a first rotation element to which the second input shaft is connected, a second rotation element to which the second output shaft is connected, and a third rotation element to which the first input shaft and the first output shaft are connected, in which an engagement device configured to selectively connect any two of the three rotation elements is provided.

A transmission with a differential locking unit which comprises an input shaft (10), first and second output shafts (11, 12), and first and second planetary gear sets (P1, P2). Torque introduced, via the input shaft (10), is converted and distributed to the two output shafts (11, 12) in a defined ratio, and development of a sum torque is prevented. The differential locking unit comprises an epicyclic gearing (P3) as well as a switching element (B 1). The epicyclic gearing (P3) has at least three connection shafts (3), a first connection shaft (WI) is rotationally fixed to a linking shaft (3), a second connection shaft (W2) is rotationally fixed to the second element (E21) of the first planetary gear set (PI), which is rotationally fixed to the first output shaft (11). A third connection shaft (W3) can be secured to a rotationally fixed component (GG) by the switching element (B 1).

A transmission with a differential locking unit which comprises an input shaft (10), first and second output shafts (11, 12), and first and second planetary gear sets (P1, P2). Torque introduced, via the input shaft (10), is converted and distributed to the two output shafts (11, 12) in a defined ratio, and development of a sum torque is prevented. The differential locking unit comprises an epicyclic gearing (P3) as well as a switching element (B 1). The epicyclic gearing (P3) has at least three connection shafts (3), a first connection shaft (WI) is rotationally fixed to a linking shaft (3), a second connection shaft (W2) is rotationally fixed to the second element (E21) of the first planetary gear set (PI), which is rotationally fixed to the first output shaft (11). A third connection shaft (W3) can be secured to a rotationally fixed component (GG) by the switching element (B 1).