A method for forming an assembly having a housing and first and second components. The first and second components are movable relative to one another in the housing. The method includes: providing first and second workpieces; moving the first and second workpieces relative to one another in a predetermined manner that produces relative sliding contact between the first and second workpieces while performing a superfinishing operation on the first and second workpieces to form the first and second components, respectively, wherein the superfinishing operation does not comprise a lapping operation; and mounting the first and second components in the housing such that the first and second components are engaged to one another and are movable relative to one another in the predetermined manner.

In at least some implementations, a torque transmitting apparatus includes a first member arranged for rotation about an axis and having a first surface oriented substantially perpendicular to the axis, and a second member having a second surface with at least a portion that is parallel to and engaged with at least a portion of the first surface. The second member is coupled to the first member by a weld provided in an interface region defined by an area of radial overlap between the first surface and the second surface. The groove is provided in one or both of the first surface and the second surface, the groove has a portion located radially inboard of the weld and at least one outlet that, at least without the weld, is communicated with a radially outer edge of the interface region.

An axle assembly and method of reworking an axle assembly. The axle assembly has an axle housing and a differential carrier assembly. A central portion of the axle housing has an opening that is defined by an axle flange that has a first mating surface. The differential carrier assembly has a differential mounted on a carrier. The carrier has a carrier flange that has a second mating surface. The first mating surface is sealed to the second mating surface by seal. At least one of the first and second mating surfaces includes a groove.

A manufacturing method for a power transmission mechanism including: first and second shafts having first and second double helical gears; first and second rolling bearings rotatably supporting the shafts with respect to a case and restrict movement of the shafts in an axial direction thereof, includes an assembling step of assembling an outer ring of the first rolling bearing and an outer ring of the second rolling bearing to the case in a state where the outer rings are movable in the respective axial directions; and a positioning step of determining axial positions of the first rolling bearing and the second rolling bearing while rotating the first shaft and the second shaft in a state where the first double helical gear and the second double helical gear are meshed with each other, after the assembling step.

A downsized differential gear unit designed to prevent transmission of an excessive torque. The differential gear unit comprises: a differential mechanism held in a casing; a ring gear mounted rotatably and reciprocatably on the casing; a friction mechanism that is arranged between the ring gear and the casing; and an elastic member that pushes the ring gear in an axial direction. A torque possible to be transmitted between the ring gear and the casing is set to a torque governed by a pushing force of the elastic member and the frictional force of the friction mechanism.

Present embodiments relate to a differential case. More specifically, but without limitation, present embodiments relate to a differential case which will function with differential components of two sizes and a rear axle housing of a different intended size.

A differential assembly and a method of manufacture. The differential assembly may include a case that is rotatable about an axis and includes a first case portion and the second case portion. The first case portion may be joined to the second case portion with a first weld that may be disposed at an angle with respect to the axis.

A differential gear includes a holder which is provided between first and second pinion gears in a differential case and through which a differential pinion shaft is inserted. An insertion hole is radially formed in the differential pinion shaft. The holder is formed with a fixing hole facing the insertion hole when the differential pinion shaft is inserted through the holder. Due to insertion of a fixing pin through the fixing hole and the insertion hole, the differential pinion shaft and the holder are relatively non-rotatable. Due to the holder being held between first and second side gears, relative rotation of the holder with respect to the differential case is restricted, and the differential pinion shaft is non-rotatable relative to the differential case.

A differential gear assembly, and method for assembling such an assembly are provided. The differential gear assembly comprises a housing constructed of substantially identically shaped and sized housing plates, which each have an outer flange of a same diameter. The assembly further comprises an outer helical ring gear that is fixed to the housing, wherein outer helical ring gear comprises an inner flange for mounting to the outer flange of the first or second housing plate, wherein an inner diameter of the inner flange is smaller than the outer diameter of the housing plates. The inner flange of the helical ring gear can thus be held, e.g. clamped, between the outer flanges of the housing plates. In an alternative embodiment, the outer flange of one of the housing plates is held between the inner flange of the ring gear and the outer flange of the other of the housing plates.

A gear box having a gear set therein for mounting to the outside of a housing of an axle assembly and connected to the input shaft of the differential of the axle assembly can allow high speed electric motor(s) to connect to the differential via the gear box for driving the axle assembly. The gear box can be mounted using existing bolt hole pattern on the axle assembly housing such as the input cover of the axle head assembly housing the differential. The gear set can be a planetary gear set where the rotor of the electric motor can be rotationally connected to the sun gear and the carrier gear can be connected to the input pinion shaft. In another embodiment an axle assembly having a differential can also have a gear box mounted to the outside of the axle housing and connected to the input pinion shaft to allow use of a high speed electric motor by providing an appropriate gear ratio conversion.