A power transmission shaft comprises a shaft unit interposed between first and second shafts; an engaged portion provided on one end of the second shaft and having an annular stepped part provided between a smaller diameter portion and a larger diameter portion; and an engaging portion provided on one end of the shaft unit and joinable with the engaged portion to rotate together about a common rotation axis, wherein the engaging portion comprises a cylindrical base portion that rotates together with the shaft unit, an elastically shrinkable cylindrical portion that is provided on one axial end of the cylindrical base portion to project toward the engaged portion and catching pawls that are provided by the elastically shrinkable cylindrical portion and latchingly engageable with the annular stepped part when the engaged portion and the engaging portion are coaxially arranged and joined with each other.

A shaft connection 1 for a longitudinal shaft assembly, has at least a first shaft having a first and second ends, and a second shaft, disposed so as to be coaxial with the first shaft, having first and second ends; the shafts extending axially. The first end forms a hollow portion. The first shaft end forms a first journal having a displacement portion. The first shaft end at least in an initial position of the shaft connection extends through the hollow portion which axially by the displacement portion forms a guide portion and circumferentially forms a form-fitting first connection. In the initial position a mutual axial displacement of the first and second shafts is prevented by an axial securing feature. In a crash the axial securing feature; is releasable by an axial release force. The first shaft is axially displaceable relative to the second shaft.

A shaft connection 1 for a longitudinal shaft assembly, has at least a first shaft having a first and second ends, and a second shaft, disposed so as to be coaxial with the first shaft, having first and second ends; the shafts extending axially. The first end forms a hollow portion. The first shaft end forms a first journal having a displacement portion. The first shaft end at least in an initial position of the shaft connection extends through the hollow portion which axially by the displacement portion forms a guide portion and circumferentially forms a form-fitting first connection. In the initial position a mutual axial displacement of the first and second shafts is prevented by an axial securing feature. In a crash the axial securing feature; is releasable by an axial release force. The first shaft is axially displaceable relative to the second shaft.

A constant velocity housing is provided to couple a plunging CV joint with a transaxle. The constant velocity comprises an elongate housing configured to retain the plunging CV joint and a splined shaft configured to engage with a transaxle. A locking system removably retains the splined shaft within the transaxle. The locking system comprises a lock pin in mechanical communication with pins slidably retained within radial holes disposed in the splined shaft underneath a snap-ring. An actuator moves the lock pin to push the pins to operably change a diameter of the snap-ring. When the actuator is loosened, the snap-ring constricts to a diameter less than the diameter of the splined shaft, allowing removal of the splined shaft from the transaxle. When the actuator is fully tightened, the snap-ring assumes a diameter greater than the diameter of the splined shaft, such that the spline shaft remains engaged with the transaxle.

A constant velocity housing is provided to couple a plunging CV joint with a transaxle. The constant velocity comprises an elongate housing configured to retain the plunging CV joint and a splined shaft configured to engage with a transaxle. A locking system removably retains the splined shaft within the transaxle. The locking system comprises a lock pin in mechanical communication with pins slidably retained within radial holes disposed in the splined shaft underneath a snap-ring. An actuator moves the lock pin to push the pins to operably change a diameter of the snap-ring. When the actuator is loosened, the snap-ring constricts to a diameter less than the diameter of the splined shaft, allowing removal of the splined shaft from the transaxle. When the actuator is fully tightened, the snap-ring assumes a diameter greater than the diameter of the splined shaft, such that the spline shaft remains engaged with the transaxle.

A joint assembly and method of utilizing the same. The joint assembly includes a first joint member drivingly connected to a second joint member by using one or more third joint members. At least a portion of a cage member is interposed between the first and second joint members. When the first joint member is plunged in a first direction, at least a portion of one or more first engagement portions of the first joint member are in direct contact with at least a portion of one or more first engagement portions of the cage member. When the first joint member is plunged in a second direction, opposite the first direction, at least a portion of one or more second engagement portions of the first joint member are in direct contact with at least a portion of one or more second engagement portions of the cage member.

A joint assembly and method of utilizing the same. The joint assembly includes a first joint member drivingly connected to a second joint member by using one or more third joint members. At least a portion of a cage member is interposed between the first and second joint members. When the first joint member is plunged in a first direction, at least a portion of one or more first engagement portions of the first joint member are in direct contact with at least a portion of one or more first engagement portions of the cage member. When the first joint member is plunged in a second direction, opposite the first direction, at least a portion of one or more second engagement portions of the first joint member are in direct contact with at least a portion of one or more second engagement portions of the cage member.

A power transmission mechanism (2) includes left and right drive shafts (3L, 3R) that transmit rotational torque from a drive source to drive wheels provided on left and right sides of a vehicle. In the right drive shaft (3R) and the left drive shaft (3L), the numbers of rolling elements (23, 33) included in plunging type constant velocity universal joints (6L, 6R) are different from each other.

A force-transmitting assembly includes a metal shaft having at least two longitudinally-extending grooves defined in an outer surface, and a metal hub having at least two longitudinally-extending grooves defined in an inner surface that surrounds the outer surface of the shaft. A plurality of discrete parts is disposed in the at least two longitudinally-extending grooves of the shaft and the hub in an interference-fit manner so as to transmit a torque from the shaft to the hub. Each of the discrete parts is composed of at least 50 mass % of technical ceramic selected from Si.sub.3N.sub.4, SiAlON, Al.sub.2O.sub.3, ZrO.sub.2, or a mixture of two or more of Si.sub.3N.sub.4, SiAlON, Al.sub.2O.sub.3, and ZrO.sub.2.

A force-transmitting assembly includes a metal shaft having at least two longitudinally-extending grooves defined in an outer surface, and a metal hub having at least two longitudinally-extending grooves defined in an inner surface that surrounds the outer surface of the shaft. A plurality of discrete parts is disposed in the at least two longitudinally-extending grooves of the shaft and the hub in an interference-fit manner so as to transmit a torque from the shaft to the hub. Each of the discrete parts is composed of at least 50 mass % of technical ceramic selected from Si.sub.3N.sub.4, SiAlON, Al.sub.2O.sub.3, ZrO.sub.2, or a mixture of two or more of Si.sub.3N.sub.4, SiAlON, Al.sub.2O.sub.3, and ZrO.sub.2.