A plunging shaft includes: a first shaft having an outer part defining a cylindrical bore and a through hole; a second shaft having an inner part; a ball spline structure connecting the outer part and the inner part so as to transmit rotational power while being relatively movable with respect to each other; and a sealing member that is inserted into the through hole to seal the through hole. The ball spline structure includes: a plurality of outer ball grooves; a plurality of inner ball grooves; a plurality of power transmitting balls; and a ball cage. The outer part is provided with an air discharging groove for discharging air in a space formed by a front end of the second shaft and the cylindrical bore when the first shaft and the second shaft move relatively move to become closer to each other.

A joint assembly (200) comprising a first joint member (232) that is drivingly connected to a second joint member (272) by one or more torque transfer elements (290). Drivingly connected to at least a portion of the second joint member (312) is a stub shaft (292). An end of the stub shaft, opposite the second joint member, is drivingly connected to at least a portion of a second shaft. At least a portion of a second end portion of a first shaft (202) is drivingly connected to at least a portion of a first end portion of the first joint member (232) and at least a portion of a first end portion of the first shaft has a gear member (210) with a plurality of gear teeth thereon.

A fixed type constant velocity universal joint has outer joint member track grooves each with a raceway center line that includes an arc-shaped portion having a curvature center that has no offset with respect to a joint center in an axial direction. The track grooves are formed such that adjacent track grooves are inclined in opposite directions. The joint also has inner joint member track grooves that are each mirror-symmetric with a corresponding one of the outer joint member track grooves. When at a maximum operating angle, a torque transmission ball that moves toward an opening side of the outer joint member track groove loses contact with an opening-side end portion of that track groove, and when at an operating angle of 0°, an end portion of a cage projects from the opening-side end portion of the outer joint member in the axial direction.

A propeller shaft including a first shaft, a first constant velocity joint drivingly connected with the first shaft, a second shaft, a second constant velocity joint drivingly connected with the second shaft, a connecting shaft drivingly connecting the first constant velocity joint and the second constant velocity joint and a grease cover disposed about an axial end of the second constant velocity joint. The second constant velocity joint is provided with a spring mechanism including a spring, wherein a spring seat of the spring mechanism is positioned on one axial end of the spring and mates with the second shaft, and wherein another axial end of the spring mates with an additional spring seat that is formed in the grease cover of the second constant velocity joint. The second constant velocity joint further comprises a spacer positioned between the spring and the grease cover and attached to the grease cover, wherein the spring has an axial end portion and a reduced diameter portion, and wherein an outer diameter of the reduced diameter portion is less than an outer diameter of the axial end portion.

A sliding constant velocity universal joint includes an outer joint member connected to a power transmission member and an inner joint member connected to an end portion of a shaft, for torque transmission between the outer joint member and the inner joint member while allowing an angle change and an axial change therebetween. The outer joint member incorporates therein an elastic member axially expandable/retractable between a tip of the shaft connected to the inner joint member and the outer joint member; the tip of the shaft is provided with a shaft protruding portion for supporting an inner diameter portion of a shaft-side end of the elastic member; the elastic member has its outer-joint-member side end provided with a receptacle for fitting into an inner diameter portion of the elastic member; the outer joint member has its inner surface press-fitted by an end plate; and the receptacle is pressed onto the end plate in the inner surface of the outer joint member.

A constant velocity joint includes an outer part having an opening and a plurality of axially extending race grooves in the opening, an inner part at least partially located in the opening and having an outer surface with a plurality of axially extending race grooves, and a plurality of balls located between in inner and outer parts in the grooves. A first subset of the race grooves in the outer part and/or a first subset the race grooves in the inner part includes a section that follows a curved path in the axial direction.

A joint assembly for a vehicle includes an outer race, a fitting, a cap and a stop member. The fitting is disposed in the outer race. The fitting is configured to be axially movable and rotationally fixed relative to the outer race. The cap is connected to the outer race. The stop member is removably received by the cap. The stop member substantially prevents axial movement of the fitting in a direction toward the cap.

A forging apparatus includes an ironing mechanism and a phase alignment mechanism. The ironing mechanism includes: a punch set, which is fitted into a cylindrical portion of a pre-processing material to be formed into the outer joint member, and is radially expandable and contractible, the cylindrical portion having grooves formed in an inner peripheral surface thereof; and a die having a hole into which the cylindrical portion is press-fitted. The phase alignment mechanism is configured to align phases of the grooves in the inner peripheral surface of the pre-processing material and phases of track groove portion forming surfaces of the punch set with each other before the pre-processing material is fitted to the punch set.

A constant velocity joint comprises an outer joint part with outer ball tracks, an inner joint part with inner ball tracks, wherein respectively an outer ball track and an inner ball track form a pair of tracks with each other; a torque-transmitting ball in each pair of tracks; a ball cage in which the torque-transmitting balls are received; wherein a first articulation angle range is defined comprising articulation angles of less than twenty degrees, and a second articulation angle range comprising articulation angles greater than twenty degrees; wherein an opening angle within the first articulation angle range increases as the articulation angle (β) increases, and wherein a first mean opening angle increase of the first articulation angle range is greater than a second mean opening angle increase of the second articulation angle range.

A constant velocity joint comprises an outer joint part with outer ball tracks and an inner joint part with inner ball tracks. An outer ball track and an inner ball track respectively form a pair of tracks with one another; in each, a torque-transmitting ball is guided. The torque-transmitting balls are accommodated in a ball cage with circumferentially distributed cage windows. In any angular position of the constant velocity joint an opening angle is formed between an outer tangent to the outer ball track and an inner tangent to the inner ball track. At an articulation angle of zero degrees the opening angle is greater than zero degrees. A central articulation angle range is defined with articulation angles less than fifteen degrees. The opening angle increases by at least two degrees within the central articulation angle range, and is less than twelve degrees for all articulation angles within the central articulation angle range.