Differential arrangement, e.g., for a drive axle of a motor vehicle. The differential arrangement comprises a drive wheel; a differential gear having an input part; a shift clutch operatively arranged between the drive wheel and the differential gear, wherein in the closed state of the shift clutch torque is transmitted from the drive wheel to the differential gear and in the open state of the shift clutch a torque transmission is interrupted. A first clutch part of the shift clutch is fixedly connected to the input part or to a differential housing of the differential gear, and a second clutch part of the shift clutch is fixedly connected to the respective other one of the input part and the differential housing.

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 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 coupling and control assembly includes first and second rotatable coupling members. The first coupling member has a first coupling face with locking formations, and the second coupling member has a second coupling face with pockets and in opposition with the first coupling face of the first coupling member and a third face spaced from the second coupling face and with passages communicating with the pockets. Locking members in the pockets transmit torque between the first and second coupling members. A stator includes an electromagnetic source, and a translator is translatable, rotatable, and coupled to the second coupling member to be rotatable therewith. The translator may include springs in the passages to actuate the plurality of locking members, or a permanent magnetic source cooperative with the electromagnetic source to translate the translator. An apertured retainer plate may be coupled to the second coupling member to facilitate pivoting of the plurality of locking members.

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.

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 clutch assembly includes a pocket plate having a pocket and a teeter-totter strut retained in the pocket. The teeter-totter strut is pivotable to an engaged position in which an engagement face of the teeter-totter strut extends out from the pocket plate. The teeter-totter strut is pivotable from the engaged position to a disengaged position in which the engagement face of the teeter-totter strut does not extend out from the pocket plate. The clutch assembly is configured so that when a shock load force acts on the teeter-totter strut, the teeter-totter strut is prevented from moving into the engaged position.

The invention is directed to a cartridge bin and a rotatable drum. The objective is to reduce labor associated with loading and unloading articles processed in a rotatable drum, for instance during laundering operations. The cartridge bin is configured to at least partially nest within the rotatable drum. Features are disclosed to rotationally align and couple these two components.

The invention is directed to a cartridge bin and a rotatable drum. The objective is to reduce labor associated with loading and unloading articles processed in a rotatable drum, for instance during laundering operations. The cartridge bin is configured to at least partially nest within the rotatable drum. Features are disclosed to rotationally align and couple these two components.

A clutch for preventing backdrive, includes a housing: a cover portion positioned on one end portion of the housing; an external shaft, at least one portion of which is positioned inside the housing, the other end portion thereof passing through the housing; a rocker positioned between the housing and the cover portion and fastened to the external shaft; an input shaft, one end portion thereof being inserted into an opening portion in the locker, and the other end portion thereof passing through the cover portion; and a gear portion positioned on the housing or the cover portion so that a serrated portion positioned on the locker is selectively brought into contact with the gear portion, wherein rotation of the rocker is restricted so that the external shaft is rotated along a rotation direction of the input shaft.