There is described a hoisting system and method of lifting that make use of a particular fibre rope. The fibre rope includes a plurality of magnets that are embedded within the fibre rope and spaced apart along the rope with a known axial distance between the magnets. The system may include a fibre rope hoisting speed sensor, and a magnetic field sensor that can sense the presence of the magnetic field of the embedded magnets. Using the sensors, the hoisting speed of the rope may be determined by: measuring the time between the passing of consecutive magnets by using the magnetic field sensor; calculating the distance between consecutive magnets using the hoisting speed sensor and the measured time between the passing of the consecutive magnets; and comparing the calculated distance between the magnets with an original, predefined distance between the magnets.

There is described a hoisting system and method of lifting that make use of a particular fibre rope. The fibre rope includes a plurality of magnets that are embedded within the fibre rope and spaced apart along the rope with a known axial distance between the magnets. The system may include a fibre rope hoisting speed sensor, and a magnetic field sensor that can sense the presence of the magnetic field of the embedded magnets. Using the sensors, the hoisting speed of the rope may be determined by: measuring the time between the passing of consecutive magnets by using the magnetic field sensor; calculating the distance between consecutive magnets using the hoisting speed sensor and the measured time between the passing of the consecutive magnets; and comparing the calculated distance between the magnets with an original, predefined distance between the magnets.

A winch assembly includes a lower body having a base, first and second sides, first and second upper body sides, a spacer positioned between the first and the upper body second sides, a first shaft extending through the upper body sides, the first shaft supporting first and second gears, a winding bar supported and rotated by the first shaft and attached to a first end of a strap, a second shaft extending through the first and second upper body sides and supporting first and second ratchet gears, the first ratchet gear meshing with the first gear and the second ratchet gear meshing with the second gear, a pawl for engaging one of the first and second ratchet gears, and a handle attached to the second shaft for rotating the second shaft, wherein rotation of the second shaft imparts rotation of the first and second ratchet gears and the first and second gears.

A winch assembly includes a lower body having a base, first and second sides, first and second upper body sides, a spacer positioned between the first and the upper body second sides, a first shaft extending through the upper body sides, the first shaft supporting first and second gears, a winding bar supported and rotated by the first shaft and attached to a first end of a strap, a second shaft extending through the first and second upper body sides and supporting first and second ratchet gears, the first ratchet gear meshing with the first gear and the second ratchet gear meshing with the second gear, a pawl for engaging one of the first and second ratchet gears, and a handle attached to the second shaft for rotating the second shaft, wherein rotation of the second shaft imparts rotation of the first and second ratchet gears and the first and second gears.

A rope fastening arrangement of a hoisting device, which comprises a rope drum, a fastening device having a chamber which defines the vertical boundary dimensions, the horizontal boundary dimensions, and depth direction boundary dimensions of the fastening device, a hoisting rope and a hoisting member which by means of the hoisting rope ascends and descends supported by the fastening device and rope drum. Said rope fastening arrangement further comprises that the hoisting rope (4) is locked to the fastening device by wedging, whereby the fastening device guides the first end of the hoisting rope away so that the first end of the hoisting rope does not extend outside the vertical boundary dimensions of the chamber.

The disclosure relates to a winding device for winding a rope onto a rope drum rotatable about a rotation axis. The winding device includes a rope guide for feeding the rope to the rope drum. The rope guide has a pivoting arm having a longitudinal axis and has a deflection element. The pivoting arm is pivotable about a pivot axis. The deflection element is disposed on the pivoting arm. The winding device is conceived such that the rope when being wound onto the rope drum passes the pivoting arm before the deflection element. The rope guide includes a delimitation element. The delimitation element is disposed such that a pivoting movement of the pivoting arm about the pivot axis is limited to a critical angular range (Δ). The deflection element is tiltable about a tilting axis. The tilting axis extends along the longitudinal axis of the pivoting arm.

A method for mounting or dismounting components of a wind turbine is provided. The mounting or dismounting is accomplished by fastening at least one retaining rope or guide rope to a component to be mounted by fastening the retaining rope or the guide rope to a rope winch unit and by raising or lowering the component to be mounted or to be dismounted by means of a crane. The component to be mounted or to be dismounted is held or guided by means of the retaining rope or guide rope. The rope winch unit comprises a base, a pivot arm and a retaining unit. The pivot arm is pivot-ably coupled to the base at its first end. A rope winch for receiving the retaining rope or guide rope is provided at its second free end. The retaining unit is pivotably coupled to the pivot arm. The base comprises a plurality of latching units for receiving a first end of the retaining unit.

A method for mounting or dismounting components of a wind turbine is provided. The mounting or dismounting is accomplished by fastening at least one retaining rope or guide rope to a component to be mounted by fastening the retaining rope or the guide rope to a rope winch unit and by raising or lowering the component to be mounted or to be dismounted by means of a crane. The component to be mounted or to be dismounted is held or guided by means of the retaining rope or guide rope. The rope winch unit comprises a base, a pivot arm and a retaining unit. The pivot arm is pivot-ably coupled to the base at its first end. A rope winch for receiving the retaining rope or guide rope is provided at its second free end. The retaining unit is pivotably coupled to the pivot arm. The base comprises a plurality of latching units for receiving a first end of the retaining unit.

A winch drum light assembly comprises a bracket having at least one attachment location for attaching the bracket to a vehicle or to a vehicle component that is attached to the vehicle; and a light member for producing light and situated on the bracket, the light member including a power connection adapted for connecting the vehicle's power or an alternative source of power to the light member.

A cable tensioning capstan assembly comprises a capstan drum and at least a first traction flange. The capstan drum may be configured to support a cable (e.g., a cable is configured to wrap around the capstan drum), and the capstan drum may be configured to rotate about an output axis. The first traction flange may be disposed adjacent the first axial end of the capstan drum and configured to rotate about the output axis. In various embodiments, the first traction flange is independently rotatable relative to the capstan drum. A clutch assembly between an input shaft and the first traction flange may facilitate the independent rotatability of the first traction flange.