A remote controlled lift assembly includes a pair of supports is each mountable to a respective outrigger of scaffolding. A winch unit is positionable on the supports when the supports are mounted on the scaffolding and the winch unit has a cable extending downwardly therefrom. The cable is lowered or lifted when the winch is actuated. A receiver is coupled to the winch unit and the receiver is in electrical communication with the winch unit. A remote control is provided that is carried by a user and the remote control is in wireless electrical communication with the receiver. In this way the user can remotely lift and lower the cable for lifting and lowering cargo.

A remote controlled lift assembly includes a pair of supports is each mountable to a respective outrigger of scaffolding. A winch unit is positionable on the supports when the supports are mounted on the scaffolding and the winch unit has a cable extending downwardly therefrom. The cable is lowered or lifted when the winch is actuated. A receiver is coupled to the winch unit and the receiver is in electrical communication with the winch unit. A remote control is provided that is carried by a user and the remote control is in wireless electrical communication with the receiver. In this way the user can remotely lift and lower the cable for lifting and lowering cargo.

A winch has a supporting frame with a first wall and a second wall. The winch also has a drum interposed between the first and second walls and is supported by them so as to rotate about its longitudinal axis which is transverse to the walls. The winch also has a flexible element for moving a load being wound around the drum. The winch also has a drive structure associated with the first wall and with a transmission structure for rotationally actuating the drum. The winch may also have a reaction element which is associated with the second wall, which supports the drum so as to rotate and which is associated with the transmission structure in order to support them.

A winch has a supporting frame with a first wall and a second wall. The winch also has a drum interposed between the first and second walls and is supported by them so as to rotate about its longitudinal axis which is transverse to the walls. The winch also has a flexible element for moving a load being wound around the drum. The winch also has a drive structure associated with the first wall and with a transmission structure for rotationally actuating the drum. The winch may also have a reaction element which is associated with the second wall, which supports the drum so as to rotate and which is associated with the transmission structure in order to support them.

A cable break-away device for a rescue hoist connects a cable to a cable drum of the rescue hoist. The cable break-away device provides overload protection to the rescue hoist by disconnecting the cable from the cable drum when the loads transmitted through cable become excessive. The cable break-away device is configured to fracture, releasing the cable from the cable drum, when the loads experienced by the cable break-away device exceed a predetermined failure set point. As such, the cable break-away device forms a mechanical fuse connecting the cable to the cable drum.

A cable break-away device for a rescue hoist connects a cable to a cable drum of the rescue hoist. The cable break-away device provides overload protection to the rescue hoist by disconnecting the cable from the cable drum when the loads transmitted through cable become excessive. The cable break-away device is configured to fracture, releasing the cable from the cable drum, when the loads experienced by the cable break-away device exceed a predetermined failure set point. As such, the cable break-away device forms a mechanical fuse connecting the cable to the cable drum.

An innovative drive system for a hoist assembly is disclosed. The hoist drive system is designed to lift at fixed speeds or at variable speeds. The hoist drive system operates with little noise and provides for minimal maintenance during the life of the hoist that requires no lubrication, has superior environmental resistance, and a compact design.

A cable break-away device for a rescue hoist connects a cable to a cable drum of the rescue hoist. The cable break-away device provides overload protection to the rescue hoist by disconnecting the cable from the cable drum when the loads transmitted through cable become excessive. The cable break-away device is configured to fracture, releasing the cable from the cable drum, when the loads experienced by the cable break-away device exceed a predetermined failure set point. As such, the cable break-away device forms a mechanical fuse connecting the cable to the cable drum.

A cable break-away device for a rescue hoist connects a cable to a cable drum of the rescue hoist. The cable break-away device provides overload protection to the rescue hoist by disconnecting the cable from the cable drum when the loads transmitted through cable become excessive. The cable break-away device is configured to fracture, releasing the cable from the cable drum, when the loads experienced by the cable break-away device exceed a predetermined failure set point. As such, the cable break-away device forms a mechanical fuse connecting the cable to the cable drum.

The present disclosure provides a winch overload protection system, a workover system, and a method for operating a workover system. The winch overload protection system, in one embodiment, includes an overload detection unit operable to detect when a load on a winch of a workover system exceeds a safety load limit. The winch overload protection system, in this embodiment, further includes an overload control unit configured to receive an overload signal from the overload detection unit, and in response thereto release a brake on the winch.