A joint assembly for use in a vehicle. The joint assembly includes a first joint member drivingly connected to a second joint member by one or more third joint members. The joint assembly further includes one or more bearing cup assemblies having a bearing cup, one or more bearings and one or more sealing members. The bearing cup has a receiving portion having a size and shape to receive and/or retain at least a portion of one or more trunnions extending from a body portion of the one or more third joint members. At least a portion of the one or more bearings are interposed between the one or more trunnions and one or more side surfaces of the receiving portion. Additionally, the one or more sealing members may be connected to and/or sealingly engaged with at least a portion of the outer surface of the one or more trunnions.

A joint assembly for use in a vehicle. The joint assembly includes a first joint member drivingly connected to a second joint member by one or more third joint members. The joint assembly further includes one or more bearing cup assemblies having a bearing cup, one or more bearings and one or more sealing members. The bearing cup has a receiving portion having a size and shape to receive and/or retain at least a portion of one or more trunnions extending from a body portion of the one or more third joint members. At least a portion of the one or more bearings are interposed between the one or more trunnions and one or more side surfaces of the receiving portion. Additionally, the one or more sealing members may be connected to and/or sealingly engaged with at least a portion of the outer surface of the one or more trunnions.

A joint assembly for use in a vehicle. The joint assembly includes a first joint member drivingly connected to a second joint member by one or more third joint members. The joint assembly further includes one or more bearing cup assemblies having a bearing cup, one or more bearings and one or more sealing members. The bearing cup has a receiving portion having a size and shape to receive and/or retain at least a portion of one or more trunnions extending from a body portion of the one or more third joint members. At least a portion of the one or more bearings are interposed between the one or more trunnions and one or more side surfaces of the receiving portion. Additionally, the one or more sealing members may be connected to and/or sealingly engaged with at least a portion of the outer surface of the one or more trunnions.

An implementation of the constant velocity (CV) joint may include a drive shaft and a housing. The drive shaft may include a first axis and a plurality of drive shaft lugs on a circumference of the drive shaft. Each of the plurality of drive shaft lugs may include a first surface having a first arcuate cross-section curved about a second axis and a second surface having a second arcuate cross-section that is curved about a third axis. The housing may include a third surface that is configured to contact the first surface to receive a rotational force from the drive shaft. The lug may define an elongate slit along a length of the lug.

An implementation of the constant velocity (CV) joint may include a drive shaft and a housing. The drive shaft may include a first axis and a plurality of drive shaft lugs on a circumference of the drive shaft. Each of the plurality of drive shaft lugs may include a first surface having a first arcuate cross-section curved about a second axis and a second surface having a second arcuate cross-section that is curved about a third axis. The housing may include a third surface that is configured to contact the first surface to receive a rotational force from the drive shaft. The lug may define an elongate slit along a length of the lug.

Disclosed is a toroidal variable speed traction drive including a driving disc and a driven disc, with a plurality of roller assemblies in between. Each roller assembly has a toroidal rolling surface to contact the toroidal surface of the corresponding disc, and a conical surface, for engaging the other roller in the assembly. An engagement is provide to prevent or reduce axial movement between the first and second rollers along the conical surface.

A proprotor system for a tiltrotor aircraft having a helicopter flight mode and an airplane flight mode includes a yoke having a plurality of blade arms each having an inboard pocket with a load transfer surface. Each of a plurality of bearing assemblies is disposed at least partially within one of the inboard pockets. Each of a plurality of inboard beams is disposed at least partially between a centrifugal force bearing and a shear bearing of each bearing assembly and has a proprotor blade coupled thereto. Each of a plurality of independent shoes is coupled between one of the centrifugal force bearings and the yoke. Each shoe has a load transfer surface that has a contact relationship with the load transfer surface of the respective inboard pocket forming a centrifugal force load path therebetween.

A proprotor system for a tiltrotor aircraft having a helicopter flight mode and an airplane flight mode includes a yoke having a plurality of blade arms each having an inboard pocket with a load transfer surface. Each of a plurality of bearing assemblies is disposed at least partially within one of the inboard pockets. Each of a plurality of inboard beams is disposed at least partially between a centrifugal force bearing and a shear bearing of each bearing assembly and has a proprotor blade coupled thereto. Each of a plurality of independent shoes is coupled between one of the centrifugal force bearings and the yoke. Each shoe has a load transfer surface that has a contact relationship with the load transfer surface of the respective inboard pocket forming a centrifugal force load path therebetween.

According to one embodiment, a constant velocity (CV) joint includes a first yoke, a second yoke, and three bearings. The first yoke is configured to be rotatably coupled to an input device about a first axis and configured to receive the input device through a first opening. The second yoke is rotatably coupled to the first yoke about a second axis and rotatably coupled to an output device about a third axis. The first bearing is disposed about the first axis adjacent to the first yoke, the second bearing is disposed about the second axis adjacent to the first yoke or the second yoke, and the third bearing disposed about the third axis adjacent to the second yoke. The first and third bearings torsionally constrain movement the first yoke and the second yoke so as to achieve a substantially CV characteristic between the input device and the output device.

According to one embodiment, a constant velocity (CV) joint includes a first yoke, a second yoke, and three bearings. The first yoke is configured to be rotatably coupled to an input device about a first axis and configured to receive the input device through a first opening. The second yoke is rotatably coupled to the first yoke about a second axis and rotatably coupled to an output device about a third axis. The first bearing is disposed about the first axis adjacent to the first yoke, the second bearing is disposed about the second axis adjacent to the first yoke or the second yoke, and the third bearing disposed about the third axis adjacent to the second yoke. The first and third bearings torsionally constrain movement the first yoke and the second yoke so as to achieve a substantially CV characteristic between the input device and the output device.