A parallel axis gear configuration constructed in accordance to one example of the present disclosure can include a first gear having a first gear tooth that includes a lead crowning across a face width thereof. The lead crowning can include (i) a first lead crown defined from a centerline to a transition point and (ii) a second lead crown defined from the transition point to a first end point. The lead crowning can include a drop-off magnitude that is greater at the second lead crown than the first lead crown.

A cap for a helical LSD is provided with: a clutch member including clutch teeth; a clutch ring including a ring portion including clutch teeth so as to mesh with the clutch member and one or more tab portions projecting radially outwardly from the ring portion; a cap main body fixed on an axial end of the casing; a receding portion of the cap main body receding from a first face toward a second face and being so dimensioned as to receive and allow the clutch ring to be axially movable, the receding portion including one or more dock portions respectively receiving the tab portions; an opening to allow access to the tab portions; side faces of the tab portions and inner faces of the dog portions so that the faces in combination axially press the clutch ring toward the clutch member; and one or more base portions.

A cap for a helical LSD is provided with: a clutch member including clutch teeth; a clutch ring including a ring portion including clutch teeth so as to mesh with the clutch member and one or more tab portions projecting radially outwardly from the ring portion; a cap main body fixed on an axial end of the casing; a receding portion of the cap main body receding from a first face toward a second face and being so dimensioned as to receive and allow the clutch ring to be axially movable, the receding portion including one or more dock portions respectively receiving the tab portions; an opening to allow access to the tab portions; side faces of the tab portions and inner faces of the dog portions so that the faces in combination axially press the clutch ring toward the clutch member; and one or more base portions.

A differential device is provided with: an input member; a gear set with output gears to transmit torque from the input member to the output gears while allowing differential motion therebetween; a first clutch for limiting the differential motion; a first pressure pressing on the first clutch; a first cam mechanism for pressing the first pressure plate toward the first clutch; a second clutch, when connected, drivingly connecting the output gears with the input member; a second pressure plate for engaging the second clutch; and a rotatable driver disk including a pressing member so coupled with the cam mechanism as to, from a first position to a second position, rotate the first cam mechanism together and to, from the second position to a third position, allow the first cam mechanism to create rotational difference relative to the pressing member, thereby engaging the second clutch.

A planetary transmission device with a small tooth number difference for implementing smart workload self-adaptation comprises a left planetary gear, a right planetary gear, a left-end disk, a right-end disk, a housing and a connection member. One end of the connection member axially run through the left planetary gear and the right planetary gear. End parts of both ends of the connection member are fixedly connected to the left-end disk and the right-end disk respectively. By means of a force closure mechanism, the transmission device can automatically and steplessly adjust a transmission ratio and an output rotation speed according to a change in load without depending on a measurement md control system, md has a simple structure and low costs.

A vehicle differential device includes a plurality of pinion gear sets. Each of the pinion gear sets includes a first pinion gear configured to mesh with a first outer helical gear and a plurality of second pinion gears configured to mesh with a second outer helical gear. The first pinion gear integrally includes an axially one end side gear portion configured to mesh with the first outer helical gear and an axially other end side gear portion configured to mesh with the second pinion gears. The second pinion gears are configured to mesh with the second outer helical gear at positions separated from each other in a circumferential direction of the second outer helical gear, and the axially other end side gear portion of the first pinion gear is configured to mesh with the second pinion gears at positions radially outward of the second outer helical gear.

A vehicle differential device comprises: a differential casing rotatably disposed around a rotational axis; and a pair of side gears rotatably supported by the differential casing and supported in a thrust direction via an annular bearing surface formed in the differential casing to mesh with a pair of pinion gears. The differential casing is provided with a first lubricating oil passage formed in a circumferential direction on an outer circumferential side of the bearing surface in the differential casing, and a first guidance projection projected toward the rotational axis in the first lubricating oil passage and guiding a lubricating oil flowing in a circumferential direction in the first lubricating oil passage due to rotation of the differential casing around the rotational axis, toward a first meshing portion between a first side gear of the pair of side gears and the pinion gears.

A vehicle differential device comprises: a differential casing rotatably disposed around a rotational axis; and a pair of side gears rotatably supported by the differential casing and supported in a thrust direction via an annular bearing surface formed in the differential casing to mesh with a pair of pinion gears. The differential casing is provided with a first lubricating oil passage formed in a circumferential direction on an outer circumferential side of the bearing surface in the differential casing, and a first guidance projection projected toward the rotational axis in the first lubricating oil passage and guiding a lubricating oil flowing in a circumferential direction in the first lubricating oil passage due to rotation of the differential casing around the rotational axis, toward a first meshing portion between a first side gear of the pair of side gears and the pinion gears.

A parallel axis gear configuration constructed in accordance to one example of the present disclosure can include a first gear having a first gear tooth that includes a lead crowning across a face width thereof. The lead crowning can include (i) a first lead crown defined from a centerline to a transition point and (ii) a second lead crown defined from the transition point to a first end point. The lead crowning can include a drop-off magnitude that is greater at the second lead crown than the first lead crown.

A parallel axis gear configuration constructed in accordance to one example of the present disclosure can include a first gear having a first gear tooth that includes a lead crowning across a face width thereof. The lead crowning can include (i) a first lead crown defined from a centerline to a transition point and (ii) a second lead crown defined from the transition point to a first end point. The lead crowning can include a drop-off magnitude that is greater at the second lead crown than the first lead crown.