A park release assembly including a package housing with a depth defining base and a cover and a cam component supported in a limited pivotal fashion within the housing. The cam component includes upper and lower portions, each further having an arcuate extending guide surface. A release cable extends in a first direction within the housing and engages the arcuate surface of the lower cam portion. An engagement cable extends in a second crosswise direction relative to the release cable and engages the arcuate surface of the upper cam portion. A pull handle is secured to an end of the engagement cable and, upon outwardly displacing the pull handle, causes concurrent rotation of the cam component in a counter biasing direction in order to linearly displace the release cable in an extending direction in order to actuate a remote lever to a vehicle Park release condition.

A vehicle door includes an actuator for operating a latching mechanism. An actuator cable extends between the actuator and the latching mechanism. A cable housing slidably receives the actuator cable. The actuator cable is operable within the cable housing between extended and retracted positions. A cable bracket secures the cable housing to a frame member in a secured position. A clip assembly attaches to the cable housing and slidably engages the actuator cable upon operation of the actuator. The clip assembly engages the cable housing at a first side of the cable bracket and engages the actuator cable at a second side of the cable bracket.

[Problem] To provide a terminal securing device the size of which can be reduced. [Solution] When a key lock 7 is positioned in a second position a key 6 and the key lock 7 are arranged at overlapping positions in the lengthwise direction of a rod 3, so a portion of a space for displacing the key lock 7 from the second position to a first position can be provided at a position overlapping the key 6 in the lengthwise direction of the rod 3. Thus, an increase in the size of a holder 4 in the lengthwise direction of the rod 3 can be avoided, so the size of the terminal securing device 1 can be reduced.

A park release assembly including a package housing with a depth defining base and a cover and a cam component supported in a limited pivotal fashion within the housing. The cam component includes upper and lower portions, each further having an arcuate extending guide surface. A release cable extends in a first direction within the housing and engages the arcuate surface of the lower cam portion. An engagement cable extends in a second crosswise direction relative to the release cable and engages the arcuate surface of the upper cam portion. A pull handle is secured to an end of the engagement cable and, upon outwardly displacing the pull handle, causes concurrent rotation of the cam component in a counter biasing direction in order to linearly displace the release cable in an extending direction in order to actuate a remote lever to a vehicle Park release condition.

Installation of a bushing into the shift cable end of an automatic transmission, without replacing the entire shift cable end, is accomplished via methods and specialized tools that do not divert the force applied by compressive tools away from the non-load-bearing surfaces of the bushing and shift cable end, and maintain the axial alignment of the bushing with the shift cable end during installation, thus preventing deformation of the shift cable end and bushing during installation, and ensuring the proper coupling of the shift cable end and shift lever. In particular embodiments, a shift cable end protective member is secured to the shift cable end, a bushing installation member is inserted into the bushing, through the shift cable end and into the protective member, and a compressive force is applied simultaneously to the protective member and installation member, thus pressing the bushing into place within the shift cable end. The protective member and installation member work in tandem to divert the compressive force away from the shift cable end, average the compressive force across the bushing, and maintain the alignment of the bushing with the shift cable end as the bushing is pressed into the shift cable end.

A motor vehicle lock module is provided for actuating a vehicle component which includes a locking element and a Bowden cable with a Bowden cable grommet and a core which is guided movably in the Bowden cable sleeve for the transmission of an adjusting force. The core is connected to the adjusting element at a first end. The Bowden cable sleeve can be received at least at a first end in an end piece. Furthermore, a one-piece seal is provided, which encloses the first end of the Bowden cable sleeve in a first region and extends in a second region via a region of the core emerging from the Bowden cable sleeve and sealing on the core is applied. The seal is designed to be pressed into the Bowden cable grommet in an end-piece-received condition in the first region from an end piece.

An unlocking device has a release lever that is connected pivotably to a carrier element and is in each case connected via Bowden cables to a catch hook for clip elements in a vehicle hood. The catch hook is moved by the Bowden cables that are actuated via the release lever, counter to the spring force of a spring element into an unlocking position for opening the vehicle hood.

Actuator (100) for an adjustable component, in particular of a motor vehicle, comprising a wire (10) made of a shape memory alloy having a first end portion (11) and a second end portion (12) and extending in an axial direction (A) over a variable length (L); an actuating element (20) movable in the axial direction (A) between a first position (I) and a second position (II); a floating support (30) by which the wire (10) is movably supported in the axial direction (A); a fixed support (33) by which the wire (10) is fixedly disposed in the axial direction (A); at least one abutment (40, 45) connected to the floating support (30) or the fixed support (33) and provided with a through-opening (41, 46) for the wire (10) and a support surface (42, 47) adapted to transmit a force in the radial direction (R); and having at least one elastically deformable connecting element (60, 65) which has a receiving opening (61, 66) for the wire (10), which has a variable diameter (D.sub.A1, D.sub.A2) and in which the wire (10) is clamped in the region of the first end portion (11) or the second end portion (12), and a contact surface (62, 67) which abuts against the support surface (42, 47) of the abutment (40, 45). By shortening the length (L) of the wire (10), a tensile force (F.sub.Z) can be transmitted from the wire (10) to the connecting element (60, 65, 69) by means of which the actuating element (20) can be moved from the first position (I) into the second position (II) and the contact surface (62, 67) can be braced against the support surface (42, 47) in such a manner that a counterforce having a component acting in the radial direction (R) is applied to the connecting element (60, 65) by the abutment (40, 45), the counterforce reducing the diameter (D.sub.A1, D.sub.A2) of the receiving opening (61, 66) in order to retain the wire (10) in the connecting element (60, 65).

The present invention aims to provide a coupling structure which facilitates work of coupling an end portion of a cable to an object to be coupled. The present invention relates to a coupling structure that couples one end of a first cable and another member. The coupling structure includes a coupling portion that couples the one end of the first cable and the other member, and a protection member that slidably houses the coupling portion. The protection member has a first opening portion which is provided at one end portion of the protection member and through which the first cable is inserted such that the first cable and the protection member are relatively movable, and a second opening portion provided at the other end portion of the protection member and from which the first cable is extendable. The coupling portion has an inclined surface that is inclined from the other member side toward the first cable side so as to abut on the second opening portion and guide the coupling portion inside the protection member in a state where the coupling portion is positioned on a radially outer side of the second opening portion when the coupling portion is relatively moved with respect to and housed into the protection member. Thus, the present invention has good coupling workability.

An end fitting device is provided for axially adjustable connection of an end portion of a motion transmitting cable to an actuating member. The end fitting device comprises a housing having a receiving space adapted for receiving the end portion of the cable via a cable entry; a connector member comprising a ball pin receiver adapted for engaging a ball pin, and having an engaged state and a disengaged state; a locking element adapted for locking the axial position of the cable end portion relative to the housing and being movable between a non-locking position and a locking position; and a force bridge connected to the locking element such that the locking element is displaced from its non-locking position to its locking position when an engaging force is applied to the end fitting device in order to bring the connector member into its engaged state.