A power transmission mechanism including a planetary mechanism, an electronically controlled clutch, and a motor generator. The planetary mechanism is coupled to an input shaft and first and second output shafts. The planetary mechanism includes a differential element rotating the first and second output shafts at different rotation speeds. The planetary mechanism outputs a torque input to the first and second output shafts. The electronically controlled clutch includes first and second clutch plates. The first clutch plate is coupled to a member different from the differential element. The second clutch plate is coupled to the differential element. The electronically controlled clutch allows the differential element to rotate the first and second output shafts at the different rotation speeds when the first and second clutch plates are released. The electronically controlled clutch restricts a rotation speed difference in response to engaging between the first and second clutch plates.

An adjuster mechanism and an axle assembly that includes an adjuster mechanism. The adjuster mechanism may include a collar assembly that has a collar that may receive a shift collar, a follower, and an adjustment screw. Rotating the adjustment screw may move the collar assembly and the shift collar along an axis.

An actuator is used to longitudinally move a spline sleeve for controlling drive mode of a differential on an off-road vehicle. The actuator's motor rotates an eccentric knob through a drive train including intermediate gears and a worm gear. The eccentic knob is linked to the spline sleeve through a torsion spring carried on a pivot plate, with legs of the torsion spring pushing a slide block, transferring a moment provided by the eccentric knob into a linear slide force. The pivot plate and torsion spring are jointly mounted on the actuator housing by a hub, opposite the rotational axis of the eccentric knob from the slide block. The slide block includes a contact which completes a circuit through conductive pads on the actuator housing, so the position of the slide block can be directly sensed.

Methods and systems for a locking mechanism in an inter-axle differential are provided. A vehicle system, in one example, includes an electric motor coupled to a clutch assembly in a locking mechanism of an inter-axle differential coupled to a first axle and a second axle, the clutch assembly is configured to selectively disengage the locking mechanism, and in the disengaged configuration the locking mechanism permits speed differentiation between the first and second axles. The system further includes an electric motor brake coupled to the electric motor and configured to selectively apply a brake torque to the electric motor and the electric motor is configured to actuate the clutch assembly.

A power transmission mechanism including a planetary mechanism, an electronically controlled clutch, and a motor generator. The planetary mechanism is coupled to an input shaft and first and second output shafts. The planetary mechanism includes a differential element rotating the first and second output shafts at different rotation speeds. The planetary mechanism outputs a torque input to the first and second output shafts. The electronically controlled clutch includes first and second clutch plates. The first clutch plate is coupled to a member different from the differential element. The second clutch plate is coupled to the differential element. The electronically controlled clutch allows the differential element to rotate the first and second output shafts at the different rotation speeds when the first and second clutch plates are released. The electronically controlled clutch restricts a rotation speed difference in response to engaging between the first and second clutch plates.

A drive unit having motor output shaft that is connected to a sun gear is connected to one or more planetary gears that are connected to a planetary gear housing. The housing is connected to planetary gear assembly pinion gear, which is connected to a ring gear. A first side of the ring gear is connected to a first clutch drum and the second side of the ring gear is connected to a second clutch drum. Connected to the first clutch drum is a first plurality of clutch plates interleafed with a second plurality of clutch plates connected to a first clutch can. The first clutch can is connected to a first shaft. Connected to the second clutch drum is a third plurality of clutch plates interleafed with a fourth plurality of clutch plates connected to a second clutch can. The second clutch can is connected to a second shaft.

Methods and systems for a locking mechanism in an inter-axle differential are provided. A vehicle system, in one example, includes an electric motor coupled to a clutch assembly in a locking mechanism of an inter-axle differential coupled to a first axle and a second axle, the clutch assembly is configured to selectively disengage the locking mechanism, and in the disengaged configuration the locking mechanism permits speed differentiation between the first and second axles. The system further includes an electric motor brake coupled to the electric motor and configured to selectively apply a brake torque to the electric motor and the electric motor is configured to actuate the clutch assembly.

An electromechanical machine that uses electrical power to provide electromechanically-balanced motive torque to one or more mechanical loads, or that uses electromechanically-balanced mechanical power from one or more sources of motive torque to supply electrical power to one or more loads, while seamlessly reconciling the speed and torque differences between such loads-and-sources by use of speed-torque modules and a control means.

The disclosure relates to a method for controlling an actuator or an actuator device, at least comprising a clutch and an actuator, which actuator has: an electric drive motor and a control device; a ramp mechanism, which comprises a rotatable first disk, which has first ramps, a second disk, which can be moved only in an axial direction and which has second ramps, and balls, which are arranged between the disks in the first ramps and second ramps; and at least one spring for moving the second disk in the axial direction. The dynamics of the electric drive motor are reduced by the control device at least in dependence on at least the determined preloading force or the first play in such a way that, during braking, the pin contacts only one side surface or that, in the event of a reversal of the rotational motion, the pin bridges the first play at a reduced first rotational speed of the drive motor and comes into contact with the other side surface and only then does an increase to a second rotational speed occur.

Methods and systems are provided for a differential lock assembly for a motorized vehicle. In one example, the differential lock assembly includes a cam gear driven by an electric motor via a transmission of the assembly. The cam gear presses a biasing member against a clutch ring in order to couple a first axle half shaft of the vehicle to a carrier of a differential, and to rotate the first axle half shaft at a same speed as a second axle half shaft driven by the differential.