A longitudinally adjustable steering shaft for a vehicle has an inner shaft received in an outer shaft to be displaceable coaxially and in the direction of a rotational axis. The two shafts have interlocking profiles in cross section for transmitting torques. A profile sleeve on which the outer shaft is telescopically arranged is arranged on the inner shaft part. The profile sleeve in a first end region surrounds a free end of the inner shaft part in the mounted state and has a radially inwardly protruding stop for abutment against an end face of the inner shaft in one axial direction and an end region of the inner shaft has a radially outwardly protruding projection for abutment of the profile sleeve in an opposite axial direction. The profile sleeve includes a radially inwardly protruding stop with reference to a simplified mounting in a first end region.

A steering shaft assembly includes a male shaft having a plurality of splines formed thereon, each of the splines terminating at a spline end, wherein each of the spline ends form an angle of about 90 degrees relative to a longitudinal direction of the splines. The steering shaft assembly also includes a female shaft including a plurality of stakes located proximate an end of the female shaft, the stakes retaining the male shaft at an interface between the stakes and the spline ends.

A vehicle shaft assembly (500). The shaft assembly includes a coupling assembly having a first (506), a second (508) and a third (510) joint member. A substantially cylindrical body portion of the second joint member is drivingly connected to a first shaft (560) having an increased diameter portion. The increased diameter portion of the first shaft has a retaining member groove (604) circumferentially extending along at least a portion of an outer surface of the increased diameter portion. At least a portion of the increased diameter portion of the first shaft is drivingly connected to a crash collapse adapter (608) having a crash collapse feature circumferentially extending along an inner surface of the crash collapse adapter. A second shaft (640) is integrally connected to at least a portion of an outer surface of the crash collapse adapter (608). At least a portion of a retaining member is disposed within the retaining member groove and the crash collapse feature.

A steering shaft having an outer shaft and an inner shaft accommodated therein in a torque-locking, axially displaceable manner and an axial inner stop which projects radially outwards from an outer face of the inner shaft. When the inner shaft is pulled out of the outer shaft, the axial inner stop strikes against an axial outer stop projecting radially inwards from an inner face of the outer shaft, wherein the axial displacement of the inner shaft is limited in the pull-out direction. With regard to simple production of the outer stops with the least possible deformation of the entire cross section of the outer shaft, the outer stop is introduced by at least one forming process into an end portion of the outer shaft, wherein the axis of the direction of introduction in each case forms an angle of more than 20° with the radial direction of the outer shaft.

A joint shaft, in particular a universal joint shaft, has first and second axial connection ends and a central part that connects the two connection ends to one another in a torsionally rigid and pivotable manner. At least one intermediate sleeve is provided between a first and a second shaft element with internal gearing having inner teeth, which are distributed over the circumference and extend in the direction of the longitudinal axis, and external gearing with outer teeth, which are distributed over the circumference and extend in the direction of the longitudinal axis. The sleeve is longitudinally displaceable relative to the first shaft element and to the second shaft element and is attached directly or indirectly in a torsionally rigid manner to the first shaft element by way of the intermediate sleeve external gearing and to the second shaft element by way of the intermediate sleeve internal gearing.

A longitudinally adjustable steering shaft for a vehicle has an inner shaft received in an outer shaft to be displaceable coaxially and in the direction of a rotational axis. The two shafts have interlocking profiles in cross section for transmitting torques. A profile sleeve on which the outer shaft is telescopically arranged is arranged on the inner shaft part. The profile sleeve in a first end region surrounds a free end of the inner shaft part in the mounted state and has a radially inwardly protruding stop for abutment against an end face of the inner shaft in one axial direction and an end region of the inner shaft has a radially outwardly protruding projection for abutment of the profile sleeve in an opposite axial direction. The profile sleeve includes a radially inwardly protruding stop with reference to a simplified mounting in a first end region.

A clip connection for connecting two components may include a latching contour arranged on the first component, and a mating latching contour arranged on the second component. The latching contour may have an arrow tip, and the mating latching contour may have a complementary opening with a periphery forming the mating latching contour. The latching contour and the mating latching contour may be positioning devices for positioning the components correctly in relation to one another.

A steering shaft assembly includes a male shaft having a plurality of splines formed thereon, each of the splines terminating at a spline end, wherein each of the spline ends form an angle of about 90 degrees relative to a longitudinal direction of the splines. The steering shaft assembly also includes a female shaft including a plurality of stakes located proximate an end of the female shaft, the stakes retaining the male shaft at an interface between the stakes and the spline ends.

A vehicle shaft assembly (500). The shaft assembly includes a coupling assembly having a first (506), a second (508) and a third (510) joint member. A substantially cylindrical body portion of the second joint member is drivingly connected to a first shaft (560) having an increased diameter portion. The increased diameter portion of the first shaft has a retaining member groove (604) circumferentially extending along at least a portion of an outer surface of the increased diameter portion. At least a portion of the increased diameter portion of the first shaft is drivingly connected to a crash collapse adapter (608) having a crash collapse feature circumferentially extending along an inner surface of the crash collapse adapter. A second shaft (640) is integrally connected to at least a portion of an outer surface of the crash collapse adapter (608). At least a portion of a retaining member is disposed within the retaining member groove and the crash collapse feature.