Transmission box (1) comprising an output shaft (5) made of a single piece or at least two shaft sections (5A, 5B), said shaft being insertable into the box (2) in the closed state of the box (2) through at least one (3) of the openings (3, 4) referred to as the insertion opening (3) in the box (2), the box (1) further comprising at least one device (8) for limiting the axial displacement of the output shaft (5) or the output shaft section (5A; 5B), this axial displacement limitation device (8) can be activated to pass from an inactive state to an active state in which any axial displacement of the output shaft (5) or of the output shaft section (5A; 5B) inside the box (1) according to at least one direction opposite to the direction of insertion of the output shaft (5) or the output shaft section into the box (1) is limited or prevented is a device (8) that can be activated in the closed state of the box (1) and is configured to, in the closed state of the box (1), to pass from an inactive state to an active state depending on the position occupied by the output shaft (5) or the output shaft section (5A; 5B) in said box (1) by simple displacement of the output shaft (5) or the output shaft section (5A; 5B) from the or at least one of the insertion openings (3) in the box (1) in the direction of the inside of the box (1).

Transmission box (1) comprising an output shaft (5) made of a single piece or at least two shaft sections (5A, 5B), said shaft being insertable into the box (2) in the closed state of the box (2) through at least one (3) of the openings (3, 4) referred to as the insertion opening (3) in the box (2), the box (1) further comprising at least one device (8) for limiting the axial displacement of the output shaft (5) or the output shaft section (5A; 5B), this axial displacement limitation device (8) can be activated to pass from an inactive state to an active state in which any axial displacement of the output shaft (5) or of the output shaft section (5A; 5B) inside the box (1) according to at least one direction opposite to the direction of insertion of the output shaft (5) or the output shaft section into the box (1) is limited or prevented is a device (8) that can be activated in the closed state of the box (1) and is configured to, in the closed state of the box (1), to pass from an inactive state to an active state depending on the position occupied by the output shaft (5) or the output shaft section (5A; 5B) in said box (1) by simple displacement of the output shaft (5) or the output shaft section (5A; 5B) from the or at least one of the insertion openings (3) in the box (1) in the direction of the inside of the box (1).

An apparatus and method for reducing edge contact stress concentrations in a press-fit. The apparatus and method of the present disclosure specifically provide for a press-fit collar having a channel circumscribing a collar axis. The channel having an asymmetrical cross-sectional profile in a radial face. The asymmetrical cross-sectional profile being configured to reduce an edge contact pressure.

An apparatus and method for reducing edge contact stress concentrations in a press-fit. The apparatus and method of the present disclosure specifically provide for a press-fit collar having a channel circumscribing a collar axis. The channel having an asymmetrical cross-sectional profile in a radial face. The asymmetrical cross-sectional profile being configured to reduce an edge contact pressure.

A structure includes a transmission axle rotatably mounted at a center of a housing. The transmission axle includes a sun gear mounted thereon. An internally-toothed ring track is fixed to an inner circumference of the housing. A planetary gear set is arranged between the sun gear and the internally-toothed ring track. The planetary gear set includes a plurality of stepped planetary gears arranged around the sun gear for self-spinning and orbiting around the sun gear. Each stepped planetary gear includes a first toothed portion meshing with both the sun gear and the internally-toothed ring track and a second toothed portion rotatable in unison with the first toothed portion. An output member is fit over the planetary gear set and includes an inner circumference formed with an internal toothed circumference meshing with the second toothed portion of each stepped planetary gear.

A structure includes a transmission axle rotatably mounted at a center of a housing. The transmission axle includes a sun gear mounted thereon. An internally-toothed ring track is fixed to an inner circumference of the housing. A planetary gear set is arranged between the sun gear and the internally-toothed ring track. The planetary gear set includes a plurality of stepped planetary gears arranged around the sun gear for self-spinning and orbiting around the sun gear. Each stepped planetary gear includes a first toothed portion meshing with both the sun gear and the internally-toothed ring track and a second toothed portion rotatable in unison with the first toothed portion. An output member is fit over the planetary gear set and includes an inner circumference formed with an internal toothed circumference meshing with the second toothed portion of each stepped planetary gear.

A spindle drive assembly for opening and/or closing a vehicle flap including a spindle drive assembly housing extending along a spindle drive axis and, between its axial ends, a stop section acting axially on both sides. A motor gear unit is arranged on a first side of the stop section and a spindle unit is arranged on a second side of the stop section. Furthermore, a vehicle flap with such a spindle drive assembly. In addition, a method of assembling a spindle drive assembly.

A spindle drive assembly for opening and/or closing a vehicle flap including a spindle drive assembly housing extending along a spindle drive axis and, between its axial ends, a stop section acting axially on both sides. A motor gear unit is arranged on a first side of the stop section and a spindle unit is arranged on a second side of the stop section. Furthermore, a vehicle flap with such a spindle drive assembly. In addition, a method of assembling a spindle drive assembly.

The present invention relates to a method for the assembly of or for preparing to assemble a traction drive module (10) in a drivetrain (2) with the method steps: providing a traction drive module (10) having a transmission housing (18) in which are arranged a first gear wheel (40) rotatably mounted on the transmission housing (18), a second gear wheel (48) arranged at a center-to-center distance (58) to the first gear wheel (40), and a traction means (46) via which the first and second gear wheel (40, 48) are in rotary driving connection with one another; attaching an assembly aid (16) acting between the second gear wheel (48) and the transmission housing (18) and detachable from the traction drive module (10); and changing the center-to-center distance (58) by moving the second gear wheel (48) relative to the transmission housing (18) while adjusting a predetermined tension of the traction means (46) by means of the detachable assembly aid (16). In addition, the present invention relates to a traction drive module (10).

A carrier assembly has a pair of axially spaced-apart plates defining an axial gap therebetween. The plates have a plurality of planetary bores on a plurality of planetary axes. A plurality of planetary gear mount assemblies are disposed on the planetary axes and mounted within the planetary bores of the gear carrier. Each assembly comprises a journal bearing shaft having a pair of compliance grooves extending axially from opposed axial ends of the shaft. An inner cylindrical surface of each compliance groove defines a shaft mounting surface. A pair of collars is provided to assemble each journal bearing shaft to the carrier. Each collar has a mounting socket mating the shaft mounting surface and an external collar surface matching the planetary bore diameter.