A complex-connection single-gear vehicle power system includes an engine, an ISG motor, an engine transmission mechanism, an electromagnetic clutch, a drive motor, a drive motor transmission mechanism and a power output shaft. The ISG motor and the drive motor are disposed on different shafts; the ISG motor is disposed on a transmission shaft of the engine transmission mechanism, or is disposed on a shaft different from the transmission shaft of the engine transmission mechanism; the electromagnetic clutch is disposed on the transmission shaft of the engine transmission mechanism or the power output shaft, and an end gear of the engine transmission mechanism is disposed at an end of the power output shaft; and an end gear of the drive motor transmission mechanism is also disposed on the power output shaft.

An actuator system for moving a plurality of pulley segments of a segmented pulley between an engaged region and a disengaged region is provided. The actuator system comprises: a deflector configured to rotate at least between a first position and a second position; and a plurality of followers, each of the followers comprising a protrusion configured to engage the deflector to move the respective one of the pulley segments between the engaged region and the disengaged region, wherein the deflector is configured to move between the first position and the second position to selectively engage the plurality of followers and direct each of the followers between an engaged position and a disengaged position, to move the plurality of pulley segments between the engaged region and the disengaged region. A segmented pulley transmission comprising the actuator system is further provided.

A drive assembly for a work vehicle includes a drive housing including a first housing element forming a reaction member; a drive shaft; a planetary gear set coupled to the drive shaft and configured to selectively rotate an output element in the first rotation direction and in the second rotation direction; a first clutch arrangement including a first clutch ring and a second clutch ring; and a second clutch arrangement to interface with the planetary gear set to selectively effect a second rotation speed of the output element in the first rotation direction and in the second rotation direction. The first clutch ring is configured to effect a first rotation speed of the output element in the second rotation direction and the second clutch ring is configured to effect the first rotation speed of the output element in the first rotation direction.

A rotational control assembly controls at least one locking element used to lock a race with respect to a housing. The rotational control assembly includes a speed sensor disposed adjacent the race. The speed sensor senses a rotational speed of the race and generating a rotational speed signal. A controller is electrically connected to the speed sensor for receiving the rotational speed signal. The controller includes a comparator to compare the rotational speed signal to a threshold speed level. A lockout switch is electrically connected to the controller. The lockout switch prevents activation of the at least one locking element when the rotational speed signal exceeds the threshold speed level. This assembly prevents attempts to synchronize or lock races when the speeds are too high. This assembly can also be used to facilitate park and hill-hold functions.

A powertrain for an electric vehicle, may include: an input shaft and an output shaft mounted in parallel to each other; first and second power transmission mechanisms provided to transmit power from the input shaft to the output shaft at two gear ratios different from each other; a one-way clutch included in the first power transmission mechanism; a friction clutch included in the second power transmission mechanism; and a bypass mechanism provided to form a power transmission path that bypasses the one-way clutch and a power transmission path that bypasses the friction clutch.

The present disclosure relates to an electric motor with an integral gearbox, and the electric motor may include a stator provided with a first member disposed on an inner circumferential surface of an enclosure to generate an electromagnetic force, a rotor provided with a second member disposed on an outer circumferential surface to face an inner circumferential surface of the stator to generate an electromagnetic force together with the first member, a gear assembly disposed with a gear tooth on an inner circumferential surface of the rotor, and provided inside the rotor, and a control unit that controls the gear assembly, wherein the gear assembly includes one or more gear plates that rotate as the rotor rotates, a connecting gear disposed to be selectively coupled to any one of the one or more gear plates, and an output shaft that rotates together as the connecting gear rotates to transmit a rotational force to the outside, and the control unit controls the moving part according to a shift signal to allow the connection gear to be coupled to or decoupled from any one of the one or more gear plates.

A drive assembly for a work vehicle has a drive housing including at least one housing element forming a reaction member, a drive shaft rotatable about a drive axis, and a planetary gear set coupled to the drive shaft and configured to selectively rotate an output element. The drive assembly also includes at least one clutch arrangement having at least one clutch ring configured to selectively interact with the planetary gear set to effect a rotation speed of the output element. At least one actuator is configured to axially drive the clutch ring along the drive axis. A retention mechanism is configured to retain the clutch ring at an axial position along the drive axis. The retention mechanism includes a detent ball, a detent groove and a resilient member configured to urge the detent ball into the detent groove to retain the clutch ring at the axial position.

A parking lock system for a motor vehicle has a housing, a drive shaft couplable to a wheel of the motor vehicle, a locking element for non-rotatably connecting the drive shaft to the housing, an actuating element for actuating the locking element, a first adjusting disc and a second adjusting disc, which are both arranged rotatably around a common axis of rotation. The system also has an adjusting device for a rotational adjustment of the first adjusting disc, a first actuator coupled to the actuating element and to the second adjusting disc. The adjusting device transmits an actuating force from the first adjusting disc, via the second adjusting disc, first actuator, and actuating element to the locking element. The parking lock system has at least one spring device, which has a first end supported at least indirectly with respect to the first adjusting disc, and a second end supported at least indirectly with respect to the second adjusting disc.

A magnetic actuator includes a first element and a second element movable with respect to the first element in a movement direction. The first element includes teeth successively in the movement direction, two coils in slots defined by the teeth, and a permanent magnet. The second element includes teeth successively in the movement direction. The teeth of the first and second elements and the permanent magnet are arranged so that the second element is held by magnetic forces in each of three positions also when there are no currents in the coils. The second element can be moved between the three positions by supplying electric currents to the coils. Thus, the second element is held in any of the three positions also when current supply to the magnetic actuator is unintentionally lost.

A transmission case houses a plurality of coupling elements and a plurality of gears therein. Each of the plurality of coupling elements may be controllable by at least one of a plurality of actuators and at least one of a plurality of struts. Actuator pads and strut pockets are formed into opposing sides of at least one side wall of the transmission case. The side wall is strong enough to receive the forces created by the strut engaging the coupling elements, while eliminating the need for an extra coupling member that otherwise extends between the transmission housing side wall and the notch plate.