A railing system is provided that illustratively includes a first rail and a second rail where the first rail is spaced-apart from the second rail. At least one cable that extends between the spaced-apart first and second rails. The at least one cable includes a stop sleeve disposed about the cable and positioned adjacent an end of the at least one cable. A cable tensioner having a body, a bore disposed through the body, and a stop surface is located adjacent an opening in the cable tensioner. An adapter that includes a body and a bore that extends into the body. The body of the adapter forms a surface located in contact with an underside surface of the top panel of the second rail between the first and second sidewalls of the second rail.

A railing system is provided that illustratively includes a first rail and a second rail where the first rail is spaced-apart from the second rail. At least one cable that extends between the spaced-apart first and second rails. The at least one cable includes a stop sleeve disposed about the cable and positioned adjacent an end of the at least one cable. A cable tensioner having a body, a bore disposed through the body, and a stop surface is located adjacent an opening in the cable tensioner. An adapter that includes a body and a bore that extends into the body. The body of the adapter forms a surface located in contact with an underside surface of the top panel of the second rail between the first and second sidewalls of the second rail.

A tensioning device includes a housing, a drive member, an inner sleeve, a driven member, a cable member, and a clutch assembly. The housing includes an attachment feature. The drive member is rotatably coupled with the housing. The inner sleeve is disposed in the housing and is coupled with the drive member. The inner sleeve is rotatable together with the drive member relative to the housing. The driven member is disposed within the housing and is operably coupled with the drive member. The clutch assembly facilitates selective coupling between the drive member and the inner sleeve. The cable member is coupled with the driven member. The driven member is slidably coupled with the inner sleeve such that the driven member and the cable member are slidable together between a retracted position and an extended position in response to rotation of the inner sleeve.

A tensioning device includes a housing, a drive member, an inner sleeve, a driven member, a cable member, and a clutch assembly. The housing includes an attachment feature. The drive member is rotatably coupled with the housing. The inner sleeve is disposed in the housing and is coupled with the drive member. The inner sleeve is rotatable together with the drive member relative to the housing. The driven member is disposed within the housing and is operably coupled with the drive member. The clutch assembly facilitates selective coupling between the drive member and the inner sleeve. The cable member is coupled with the driven member. The driven member is slidably coupled with the inner sleeve such that the driven member and the cable member are slidable together between a retracted position and an extended position in response to rotation of the inner sleeve.

A cable railing system is provided that includes cables connected to two or more supporting structures secured to a surface, for example vertical railing posts on a deck. The ends of the cables may be fitted with lag screws allowing the cable to be securely attached to the supporting structures. The lag screws have external threads that are larger than the diameter of the body where rotating the head component of the lag screws drive the lag screws into the supporting structures. The lag screws have a head component with a central bore and body component with a hollow cavity and an ending point whereby the cable is inserted into the hollow cavity through the central bore and positioned at the ending point where it then can be crimped in place and then tightened by twisting the head component.

A cable railing system is provided that includes cables connected to two or more supporting structures secured to a surface, for example vertical railing posts on a deck. The ends of the cables may be fitted with lag screws allowing the cable to be securely attached to the supporting structures. The lag screws have external threads that are larger than the diameter of the body where rotating the head component of the lag screws drive the lag screws into the supporting structures. The lag screws have a head component with a central bore and body component with a hollow cavity and an ending point whereby the cable is inserted into the hollow cavity through the central bore and positioned at the ending point where it then can be crimped in place and then tightened by twisting the head component.

A piece of playground equipment is disclosed and includes a system for tensioning one or more cables. The system includes a cable retaining device having a cylindrical shaped body with threads disposed around an outer circumferential surface, the outer circumferential surface being interrupted in at least one location by one or more cable receiving channel. The system also includes a tightening sleeve into which the cable retaining device is configured to be threaded such that the cable retaining device moves as the tightening sleeve is rotated.

A piece of playground equipment is disclosed and includes a system for tensioning one or more cables. The system includes a cable retaining device having a cylindrical shaped body with threads disposed around an outer circumferential surface, the outer circumferential surface being interrupted in at least one location by one or more cable receiving channel. The system also includes a tightening sleeve into which the cable retaining device is configured to be threaded such that the cable retaining device moves as the tightening sleeve is rotated.

Various embodiments concern locking release mechanisms that allow an articulated support arm to be moved between various vertical orientations. A locking release mechanism may include a handle release mechanism positioned within the handle of the articulated support arm, and a gas spring release mechanism positioned within the body of the articulated support arm. The articulated support arm can include a gas spring that remains locked until the handle release mechanism is activated, e.g. by applying pressure to a grip actuator. Other embodiments concern cable management techniques for articulated support arms. Oftentimes, an articulated support arm will include cables routed through the arm that are configured to support an attachment. For example, the cable(s) may be adapted for audio signals, video signals, power, etc. The cable(s) can be readily cleaned and/or serviced when routed through an articulated support arm composed of one or more removable pieces.

Various embodiments concern locking release mechanisms that allow an articulated support arm to be moved between various vertical orientations. A locking release mechanism may include a handle release mechanism positioned within the handle of the articulated support arm, and a gas spring release mechanism positioned within the body of the articulated support arm. The articulated support arm can include a gas spring that remains locked until the handle release mechanism is activated, e.g. by applying pressure to a grip actuator. Other embodiments concern cable management techniques for articulated support arms. Oftentimes, an articulated support arm will include cables routed through the arm that are configured to support an attachment. For example, the cable(s) may be adapted for audio signals, video signals, power, etc. The cable(s) can be readily cleaned and/or serviced when routed through an articulated support arm composed of one or more removable pieces.