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.

The disclosure relates to a component system of a vehicle comprising a vehicle element which is displaceable in relation to a base element and connected to a drive cable system which can be driven by a drive and comprises a first cable unit and a second cable unit which is connected to the first cable unit via a connecting unit. The connecting unit comprises a coupling box in which a spring element acting on a cable of the first cable unit is disposed.

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.

To provide a cable joint including a joint piece which has an good sliding property and is hardly broken. The cable joint includes a joint case 10 and a joint piece 50. The joint piece 50 is provided with a locking part of a cable end and a cable lead-out groove 56. A joint case side main sliding surface 21a is formed flat, and a protrusion part 61 is provided on a joint piece side main sliding surface 60. The protrusion part protrudes toward the main sliding surfaces 60, 21a in a direction orthogonal to the main sliding surfaces. An apex part 61a of the protrusion part is located at a position corresponding to the cable lead-out groove 56 in the direction orthogonal to the main sliding surfaces.

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.

Provided is a cable connecting mechanism including a slider and a slider housing member. The slider housing member has a lid member, a bottom surface member, a pair of side walls, a one-end-side hinge connecting the lid member and the bottom surface member, an another-end-side hinge connecting the member and the bottom surface member, a first engagement structure provided on an outer surface closer to one end of the slider housing member than the one-end-side hinge, a second engagement structure, a third engagement structure, a fourth engagement structure, a cable extension part, and a wall portion arranged to be sandwiched between the one-end-side hinge and the another-end-side hinge. In a closed state, when a load is applied to the cable so as to release the closed state by pressing at least one of the lid member and the bottom surface member, the wall portion abuts against an outer circumference of another one of the lid member and the bottom surface member, to restrict a movement of the lid member or the bottom surface member in an alignment direction of the pair of side walls. Therefore, the hinge is not easily broken.

A cable actuator system includes an actuating cable for connection to an actuator and to an actuatable device and a bypass assembly connected to the actuating cable. The bypass assembly includes a bypass input with a first input position and with a second input position. With the bypass input in the first input position the bypass assembly acts on the cable such that an actuating movement of the cable by the actuator moves the cable an actuating distance at the actuatable device to actuate the actuatable device. With the bypass input in the second input position the bypass assembly acts on the cable such that the actuating movement of the cable by the actuator does not move the cable the actuating distance at the actuatable device. A vehicle seat, with a seat base, a backrest, an actuator, and a vehicle seat actuatable device, also includes the cable actuator system.

A motion transmitting remote control assembly (100) comprises a first conduit section having a first end fitting (114) extending along a first longitudinal axis, and a second conduit section having a second end fitting (120) extending along a second longitudinal axis. The second end fitting has an open position where the second axis is transverse to the first axis, and a closed position where a portion of the first and second axes align. A first core element has a first coupler (128) mounted thereto, and a second core element has a second coupler (140) mounted thereto. A guide mechanism (144) having a first portion coupled to the first end fitting and a second portion coupled to the second end fitting, aligns the end fittings when the second end fitting is in the open position. The guide mechanism also guides the second end fitting toward the first end fitting until the second end fitting is in the closed position.

The present invention relates to a steel wire and transmission shaft connecting structure, a surgical robot, and a method. A base is included. Multiple transmission shafts penetrate through the base. A clamping block is arranged at one end of the transmission shaft. The transmission shaft is detachably clamped and fixed to a quick-connect shaft through the clamping block and a clamping slot structure arranged at one end of the quick-connect shaft. The other end of the quick-connect shaft penetrates through a butting seat and is then detachably fixed to a steel wire extending from a pipeline member. A shifting clamp is arranged between the butting seat and the pipeline member. The shifting clamp is provided with a through hole configured for the butting shaft to penetrate through. The through hole is composed of a first hole portion and a second hole portion.

A seal structure includes an insertion path which connects between a first opening and a second opening and through which a longitudinal member is inserted; and a seal part, formed at the intermediate section of the insertion path, which contacts with the outer circumference of the inserted longitudinal member. A discharge path is provided on a side wall section of the insertion path, and connects from the side surface of the side wall section to a section, of the insertion path, which is closer to an inflow opening through which flowing water is likely to flow than the seal part is to the inflow opening. The discharge path is structured in communication with a gap, formed between the outer circumference of the longitudinal member and the inner surface of the insertion path, which allows for inflow of flowing water along the direction in which the longitudinal member is inserted