Proposed is a disconnector apparatus including: a support ring provided in a differential casing and configured to support a pinion gear mounted therein; a clutch ring configured to be coupled to or decoupled from the support ring in the differential casing; an actuator including an armature provided at an outer side of the differential casing opposite to the clutch ring, the actuator being configured to couple the clutch ring and the support ring by pulling, with an electromagnetic force, the armature connected to the clutch ring by an application rod; and an elastic member coupled to a portion of the application rod in the differential casing and having one end in contact with the differential casing and the other end in contact with the clutch ring to elastically support the clutch ring.

A vehicle differential may have multiple gears and include a coil, a drive member movable in response to a magnetic field generated by the coil, with the drive member being movable between a first position and a second position. The drive member has an axis and includes a first body that is magnetically responsive, a second body coupled to the first body, an axis, an axially forward face and a stop surface axially spaced from the forward face, where the stop surface is arranged to limit movement of the drive member away from the first position. A lock member is engaged and driven by the forward face of the drive member to engage a gear of the differential when the drive member is in the second position, and the lock member is adapted to be disengaged from the gear when the drive member is in the first position.

A vehicle differential may have multiple gears and include a coil, a drive member movable in response to a magnetic field generated by the coil, with the drive member being movable between a first position and a second position. The drive member has an axis and includes a first body that is magnetically responsive, a second body coupled to the first body, an axis, an axially forward face and a stop surface axially spaced from the forward face, where the stop surface is arranged to limit movement of the drive member away from the first position. A lock member is engaged and driven by the forward face of the drive member to engage a gear of the differential when the drive member is in the second position, and the lock member is adapted to be disengaged from the gear when the drive member is in the first position.

Drivetrain systems and methods are provided. In one example, the drivetrain system includes an interaxle differential (IAD) configured to receive power from a prime mover, a motor configured to drive a planetary gearset, and a ball ramp actuator configured to selectively engage a plurality of plates in a clutch pack of a friction clutch in response to receiving rotational input from the planetary gearset. In an engaged configuration, the friction clutch prevents speed differentiation between a first IAD output and a second IAD output.

Drivetrain systems and methods are provided. In one example, the drivetrain system includes an interaxle differential (IAD) configured to receive power from a prime mover, a motor configured to drive a planetary gearset, and a ball ramp actuator configured to selectively engage a plurality of plates in a clutch pack of a friction clutch in response to receiving rotational input from the planetary gearset. In an engaged configuration, the friction clutch prevents speed differentiation between a first IAD output and a second IAD output.

Methods and systems for a locking differential are provided. The locking differential system includes an electromagnetic solenoid actuator configured 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 multi-sensor sub-assembly having two or more sensor configured to monitor a position of the electromagnetic solenoid actuator.

Methods and systems for a locking differential are provided. The locking differential system includes an electromagnetic solenoid actuator configured 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 multi-sensor sub-assembly having two or more sensor configured to monitor a position of the electromagnetic solenoid actuator.

A drivetrain component provides an electronically controlled, overrunning drivetrain disconnect, such as a differential with different operating modes. The drivetrain component includes a case having an annular wall portion with a plurality of pockets in one side. The carrier is supported for movement relative to and independently of the case. The carrier includes a notch plate. The differential gear set has a pinion shaft tied to the carrier, pinion gears mounted on the pinion shaft, differential gears engaging the pinion gears, and differential gear shafts connected to the differential gears. The drivetrain component includes a first locking structure and a second locking structure. Both the first and second locking structures are on the same side of the notch plate. The first locking structure couples the case to the carrier for torque transmission from the case to the carrier in a first direction only, wherein the first locking structure does not inhibit carrier rotation in a second direction.

A drivetrain component provides an electronically controlled, overrunning drivetrain disconnect, such as a differential with different operating modes. The drivetrain component includes a case having an annular wall portion with a plurality of pockets in one side. The carrier is supported for movement relative to and independently of the case. The carrier includes a notch plate. The differential gear set has a pinion shaft tied to the carrier, pinion gears mounted on the pinion shaft, differential gears engaging the pinion gears, and differential gear shafts connected to the differential gears. The drivetrain component includes a first locking structure and a second locking structure. Both the first and second locking structures are on the same side of the notch plate. The first locking structure couples the case to the carrier for torque transmission from the case to the carrier in a first direction only, wherein the first locking structure does not inhibit carrier rotation in a second direction.

Provided is a wheel driving device in which a lock operation mechanism can be disposed without increasing the width of a housing. In a wheel driving device, the housing includes support walls and a peripheral wall continuous to the support walls, a rotary shaft that rotatably supports a diff-lock fork around the axis orthogonal to the rotation axis of the differential gear is provided at a boundary between the peripheral wall and one of the support walls, the diff-lock fork includes one end portion extending along the support wall and the other end portion extending along the peripheral wall, the one end portion is engaged with a lock slider of the differential gear, and the other end portion is engaged with an actuator installed on the peripheral wall.