A control device for a human powered vehicle includes a base member configured to clamp a handlebar. The base member defines a clamping axis in a mounted state where the base member clamps the handlebar. The control device includes an operating member configured to be arranged by sliding movement on the base member between a rest position and an operated position in a circumferential direction of the base member. The operating member has a connecting portion to which a control cable is connected. The operating member is removably arranged on the base member, and the operating member is positioned on the base member with a tension of the control cable. The control device includes an inner member configured to be accommodated in the base member and to be arranged around the handlebar such that the operating member is at least partly arranged between the base member and the inner member.

A cable adjuster is provided for a small vehicle including a bicycle. The cable adjuster includes a base portion and a control structure. The control structure includes a first member, a second member and a clutch mechanism. The first member is configured to be rotatably mounted to the base portion about a first axis. The second member is attached to the first member to rotate relative to the first member. The clutch mechanism is configured to transmit rotational force applied to the second member to the first member. The clutch mechanism is also configured to prevent from transmitting rotational force applied on the first member to the second member.

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.

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.

A telescopic transmission assembly includes first and second stage rods, and first and second stage casings. The second stage rod is of a hollow structure having inner and outer surfaces and a through hole, the outer surface being provided with external threads, and the inner surface being devoid of threads. The first stage rod is disposed in the through hole to drive the second stage rod to rotate synchronously. The first and second stage rods are telescopically expandable or contractible relative to each other along an axial direction. The second stage casing sleeves over the first stage casing. The first and second stage casings have respectively first and second transmission nuts. The second and first stage rods are in a screw-thread fit with the first and second transmission nuts, respectively. The second stage rod is positioned with the first transmission nut in the axial direction in a rotatable manner.

A control device for a human powered vehicle includes a base member configured to clamp a handlebar. The base member defines a clamping axis in a mounted state where the base member clamps the handlebar. The control device includes an operating member configured to be arranged by sliding movement on the base member between a rest position and an operated position in a circumferential direction of the base member. The operating member has a connecting portion to which a control cable is connected. The operating member is removably arranged on the base member, and the operating member is positioned on the base member with a tension of the control cable. The control device includes an inner member configured to be accommodated in the base member and to be arranged around the handlebar such that the operating member is at least partly arranged between the base member and the inner member.

A cable adjustment mechanism for connecting a cable assembly comprising a cable to a bracket, the mechanism comprising: a connecting bushing having a bracket connector for attaching to the bracket, a first body interior for receiving the cable there though, and a cable connector for attaching to the a mechanism body of the cable assembly; the mechanism body having a second body interior for receiving the cable there though, a first end, and a second end for receiving the connecting bushing, the first end opposed to the second end, the second body interior defining an adjustment axis; a spacing member having one end for coupling to a cable body of the cable assembly and another end for coupling with the mechanism body at the first end, the another end opposed to the one end, the spacing member having a third body interior for receiving the cable there through; and a lock for retaining a selected relative position on the mechanism body along the adjustment axis in order to retain a resultant separation distance between the connecting bushing and the cable body; wherein the selected relative position is determined by adjusting a position of the coupling of the one end with respect to the first end along the adjustment axis prior to locking the selected relative position by the lock.

A cable pull for transmitting a tensile and/or pressure force to a pivot point is presented. The cable pull has a counter bearing, a tie rod, an adjustment unit and a locking element. The counter bearing is designed to introduce a counter bearing into a casing of the cable pull, counter to the tensile and/or pressure force. The tie rod is axially supported in the counter bearing, and coupled to a wire core of the cable pull. The tie rod has a molded part on an end protruding out of the counter bearing, having a first component of a toothing. The adjustment element is designed to adjust a length of the cable pull between the counter bearing and the pivot point. The adjustment element has a guide for the molded part. The molded part can move axially in the guide, and is disposed such that it is guided transverse thereto. The locking element is designed to fix the molded part in place in the adjustment unit. The locking element is disposed in a recess in the adjustment unit oriented transverse to the guide, and can move between a locking position and an adjustment position. The locking element has a second component of the toothing, which is designed to engage in the first component in a form fitting manner when in the locking position, and to suppress the axial movement of the molded part in the guide.

An attachment assembly for securing a transmission shifter cable includes an outer frame and an inner frame disposed at least partially within the outer frame and axially movable relative to the outer frame. The attachment assembly further includes an attachment block disposed at least partially within the inner frame and axially movable relative to the inner frame. An axial displacement of the attachment block secures the inner frame to the outer frame to inhibit axial movement of the inner frame relative to the outer frame.

Cable splitter devices, assemblies, and methods of use are disclosed. A cable splitter device is disclosed. A cable splitter assembly includes a housing, a slider, first cables, and second cables. The housing defines a first number of first slots and a second number of second slots different from the first number. The slider is slidably coupled to the housing. The slider defines the first number of first channels and the second number of second channels. The first cables extend through the first number of first slots and have an end positioned within a respective first channel of the slider. The second cables extend through the second number of second slots and have an end positioned within a respective second channel of the slider. A clipping element may be configured to fix a longitudinal position of a respective first cable at multiple different locations along the first channel.