A differential gear including a rotatably mounted differential housing and a final driven gear mounted rotationally fixed to the differential housing. The differential housing, on the outer circumferential surface thereof, includes two mating surfaces and that the final driven gear, on the inner circumferential surface thereof, includes two radially opposite mating surfaces. The mating surfaces formed on the outer circumferential surface of the differential housing and the mating surfaces formed on the inner circumferential surface of the final driven gear are each designed as separate mating surfaces which, when viewed in axial direction (a), are arranged geometrically separated from each other by a spacing.

A differential gear assembly for a vehicle includes: an annular ring gear having internal and external surfaces, and rotates around a rotational axis extending in an axial direction; first and second side gears respectively distribute a first and second output torque to first and second drive shafts; first and second differential pinion gears respectively engage the first and second side gears; a pinion pin extends diametrically across the ring gear, where the first and second differential pinion gears are rotatably arranged on the pinion pin. The ring gear comprises first and second slots for receiving the pinion pin, where the slots are arranged in connection to the internal surface and extend partly through the ring gear in the axial direction.

A method of machining a carrier housing for an axle assembly comprises obtaining a carrier housing including circumferentially spaced apart tabs and positioning a datum setting tool in engagement with the carrier housing. The carrier housing is clamped to a fixture to position the carrier housing at a first orientation relative to a coordinate system within a work cell. The datum setting tool is disengaged from the carrier housing. Portions of the carrier housing along a first side are machined to define features including a carrier mounting flange and a cylindrical bearing bore extending perpendicular to the carrier mounting flange while the carrier housing remains clamped at the first orientation. Different portions of the carrier housing, on a second opposite side of the carrier housing, are machined to define additional geometrical feature while the initial clamped orientation continues to be maintained.

A joining outer diameter portion located at an axial-direction intermediate portion and fitting tapered outer diameter portions located on both axial-direction sides across the joining outer diameter portion are formed on an outer peripheral face portion of an inner metal member. A joining inner diameter portion corresponding to the joining outer diameter portion and having a smaller diameter than the joining outer diameter portion so as to overlap with the joining outer diameter portion, and fitting tapered inner diameter portions corresponding to the fitting tapered outer diameter portions are formed on an inner peripheral face portion of an outer metal member. The joining portions are joined by means of resistance heating generated by conducting electricity while they are pressurized in the axial direction. The fitting tapered portions are brought into a fitted state in association with the joining.

A method of making an interaxle differential unit. The method may include piercing a workpiece and then ring roll forging the workpiece to form an annular case that is a seamless ring. The annular case may be heat treated before installing an interaxle differential unit gear nest inside the annular 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 method of machining a carrier housing for an axle assembly comprises obtaining a carrier housing including circumferentially spaced apart tabs and positioning a datum setting tool in engagement with the carrier housing. The carrier housing is clamped to a fixture to position the carrier housing at a first orientation relative to a coordinate system within a work cell. The datum setting tool is disengaged from the carrier housing. Portions of the carrier housing along a first side are machined to define features including a carrier mounting flange and a cylindrical bearing bore extending perpendicular to the carrier mounting flange while the carrier housing remains clamped at the first orientation. Different portions of the carrier housing, on a second opposite side of the carrier housing, are machined to define additional geometrical feature while the initial clamped orientation continues to be maintained.

A vehicle driveline component with a differential case, a cross-pin, a differential gearset, and a retaining member. The differential case is rotatable about a first axis and has an annular wall member that defines a differential cavity. The cross-pin is received in a cross-pin aperture formed through a first side of the annular wall member. The cross-pin extends through the differential cavity along a second axis that is perpendicular to the first axis. The differential gearset is received in the differential cavity and includes a pair of side gears, which are rotatable about the first axis, and a pair of pinion gears that are journally supported by the cross-pin and meshingly engaged with the side gears. The retaining member is welded to the annular wall member and limits movement of the cross-pin relative to the differential case along the second axis in a direction toward the retaining member.

A method for assembling an axle assembly for a vehicle including that a pinion gear is inserted into a differential housing. The pinion gear having a first end and a second end opposite the first end. The pinion gear further includes a gear head at the first end, external threads proximate the second end, and external splines located a first distance away from the second end. The method further includes that a flange is slid over the second end of the pinion gear. The flange including internal splines. The method also includes that the internal splines of the flange are engaged with the external splines of the pinion gear and the flange is anchored to prevent the flange and the pinion gear from rotating. The method may further include that ultrasonic sound waves are transmitted through the pinion gear and reflections of the ultrasonic sound waves are detected.

A method of joining two ferrous alloy component parts. The method includes hot metal casting a portion of a first ferrous alloy component part onto a first joining surface of a low carbon intermediate element; friction fitting a joining surface of a second ferrous alloy component part against a second joining surface of the low carbon intermediate element; and fusion welding with a concentrated energy source the intermediate element to the second ferrous alloy component part. The hot metal casting includes flowing a molten ferrous alloy onto the textured first joining surface, wherein the molten ally encompasses tabs extending from the first joining surface and filling apertures defined in the intermediate element. Then cooling the molten ferrous alloy such that a metallurgical and mechanical bond is formed between the portion of the first ferrous alloy component part and the first joining surface of the low carbon intermediate element.