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 driveline component with a housing, a tube and a plurality of slugs. The housing has a tube mount with a body and a plurality of slug bores. The body defines a tube bore that extends along an axis. The slug bores are spaced circumferentially apart about and are formed through the body. Each of the slug bores intersects the tube bore. The tube is received in the tube bore. Each of the slugs is received into an associated one of the slug bores and is welded to the tube. Each of the slugs engages an inside surface of one of the slug bores to inhibit movement of the tube relative to the tube mount. The body has a wall thickness and each of the slugs engages the inside surface of one of the slug bores over a distance that is less than the wall thickness.

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.

An automotive axle includes a housing including gears and a bath lubricating the gears, the bath including gear oil and about 0.1 to 5 wt. % secondary alcohol ethoxylate based on total weight of the bath such that during automotive operation at temperatures less than a threshold, reverse micelles form to trap air bubbles in the bath, emulsifying the bath, and at temperatures greater than the threshold, the reverse micelles dissipate.

An automotive axle includes a housing including gears and a bath lubricating the gears, the bath including gear oil and about 0.1 to 5 wt. % secondary alcohol ethoxylate based on total weight of the bath such that during automotive operation at temperatures less than a threshold, reverse micelles form to trap air bubbles in the bath, emulsifying the bath, and at temperatures greater than the threshold, the reverse micelles dissipate.

One aspect of the disclosure relates to a sliding member. The sliding member includes: a first sliding portion having a first lubricant placed between first parts of a first friction sliding mechanism; a second sliding portion having a second lubricant placed between second parts of a second friction sliding mechanism; and a third sliding portion having a third lubricant placed between third parts of a third friction sliding mechanism. The first sliding portion is in contact with the third lubricant, and the second sliding portion is not in contact with the third lubricant. The second lubricant contains an additive containing conductive carbon, and the third lubricant contains no conductive carbon. The second lubricant contains a relatively larger amount of the conductive carbon than the first lubricant.

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.

A carrier can comprise a through-port in a carrier plate. A threaded connection can comprise a threaded cap comprising a tubular body, a central port through the tubular body, and a rim clenching a face seal to the carrier plate when a nut is tightened to the threaded cap. A plenum in a case can be installed in the carrier. The case can comprise a case portion seating a piston and forming the plenum. The piston can be configured to actuate in the plenum in a first axial direction upon supply of hydraulic fluid to the plenum. A plenum port can extend from the case portion. The plenum port can be configured to communicate hydraulic fluid to the plenum to actuate the piston. The central port of the threaded connection can comprise a hydraulic tube mounted directly or indirectly to the plenum port to supply the hydraulic fluid.