A locking differential assembly includes a differential case, a first output shaft and a second output shaft. A first side gear is non-rotatably coupled to the first output shaft and a second side gear is non-rotatably coupled to the second output shaft. A differential pin is also included, the differential pin having differential gears. The differential gears are rotatably supported by the differential case and drivingly engaged with the first and second side gears to allow differential rotation thereof. A lock mechanism is actuated when a first torque force is applied to a drive cam and a driven cam. Finally, an electromagnetic coil actuates a brake plate, wherein the brake plate comes into frictional with a brake disc. Furthermore, the electromagnetic coil is discontinuous around the circumference of the brake disc.

A vehicle driveline component includes a case defining lever apertures, a coupling having a movable member that is movable along a movement axis between a first and a second position, a linear having a motor output member movable along the movement axis, and a plurality of levers. Each lever is disposed in an associated lever aperture and coupled to the case for pivoting motion about a respective lever pivot axis. The levers urge the movable member in a first direction along the movement axis from one of the first and second positions to the other one of the first and second positions in response to pivoting motion of the levers about the lever pivot axes caused by contact between the levers and the motor output member when the motor output member is driven in a second direction along the movement axis that is opposite the first direction.

A final reduction apparatus includes a carrier, a differential device, a clutch member for interrupting a differential movement of the differential device, and an actuator for operating the clutch member. The clutch member is accommodated in a differential case of the differential device. The actuator is disposed outside the differential case. The carrier includes a main body in which an opening is formed and a cover that closes the opening. The differential device is insertable via the opening into the main body. The actuator is disposed on a side of the cover that is, on an opposite side of the actuator with respect to the opening than the differential device.

Methods and systems are provided for a sensor assembly for a differential apparatus. In one example, the sensor assembly includes a microcontroller and an eddy current sensor communicatively coupled to the microcontroller and configured to detect a distance between an axially slidable and an axially stationary component of a differential apparatus.

A locking differential assembly (10) includes a differential case (12). A lock ring (40) is selectably engagable with a first side gear (18, 20) to selectably prevent the first side gear (18, 20) and a second side gear (18, 20) from rotating relative to the differential case (12). A plunger (30) is translatable along a plunger axis (55) through a bore (68) in the differential case (12). The plunger (30) is to be in contact with the lock ring (40) at least when the lock ring (40) is engaged with the first side gear (18, 20). A position of the plunger (30) relative to the differential case (12) along the plunger axis (55) is indicative of an engagement status of the lock ring (40). A non-contacting sensor is connected to the differential case (12) and located a fixed, predetermined distance from the differential case (12). The sensor is to detect a proximity of the plunger (30) to the sensor and to output an electrically detectable signal indicative of the engagement status of the lock ring (40).

A power transmission device is provided with: a rotary body arranged to receive the torque to rotate about an axis; a clutch including a clutch member engaging with the rotary body and axially movable and clutch teeth connectable with the clutch member to transmit the torque; a solenoid configured to generate a magnetic flux in response to input of electric power; a stator coupled with the solenoid as to conduct the magnetic flux and prevented from rotation about the axis; a rotor arranged to receive the magnetic flux from the stator and, when driven by the received magnetic flux, to create a rotational motion about the axis; and a conversion mechanism drivingly connected with the rotor to convert the rotational motion into a linear motion in a direction along the axis, the conversion mechanism including a thrust member transmitting the linear motion to the clutch member.

An electronically actuated locking differential includes a gear case having opposite first and second ends, a differential gear set disposed in the gear case, a lock plate disposed at the gear case first end and configured to selectively engage the differential gear set, and an electronic actuator disposed at the gear case second end and coupled to the lock plate via at least one rod. The electronic actuator is operable between an unlocked first mode where the lock plate does not lockingly engage the differential gear set, and a locked second mode where the electronic actuator pulls the at least one rod to thereby pull the lock plate into locking engagement with the differential gear set to thereby lock a pair of axle shafts.

A vehicle driveline component includes a case defining lever apertures, a coupling having a movable member that is movable along a movement axis between a first and a second position, a linear having a motor output member movable along the movement axis, and a plurality of levers. Each lever is disposed in an associated lever aperture and coupled to the case for pivoting motion about a respective lever pivot axis. The levers urge the movable member in a first direction along the movement axis from one of the first and second positions to the other one of the first and second positions in response to pivoting motion of the levers about the lever pivot axes caused by contact between the levers and the motor output member when the motor output member is driven in a second direction along the movement axis that is opposite the first direction.

An electronic locking differential that includes a movable electromagnet to selectively operate a dog clutch for locking a side gear to a carrier. The dog clutch includes a dog member having a plurality of legs that extend through leg apertures in the carrier. A cam mechanism is employed on the legs and the carrier to generate and apply a force to the dog member to maintain the dog member in an engaged position when torque is transmitted through the cam mechanism. The carrier is configured with an annular rib that surrounds a pocket. The annular rib has a frustoconical shape that matches that of a pole piece on the electromagnet. The electromagnet is received into the pocket when the electromagnet is operated and the dog member is in its engaged position.

Methods and systems for a locking differential are provided. The locking differential system includes an electromagnetic solenoid actuator designed to induce locking and unlocking of the differential and a circuit board assembly designed to programmatically control the locking and unlocking functionality. The circuit board assembly includes a sensor and control circuity enclosed in a continuous sealed enclosure, the sensor extends down the face of a coil assembly in the solenoid.