A method for adapting a travel end position of a changing movement of a thread to a flange spool includes means of which the thread is moved back and forth during a spooling operation along a rotation axis of the flange spool relative to the flange spool by means of a changing thread guide. The flange-side travel end position can be moved away from the flange of the flange spool in an axial direction when the thread tension decreases when the thread is moved away from the flange-side travel end position. Also, the flange-side travel end position can be moved by means of the changing thread guide in an axial direction towards a flange of the flange spool when the thread tension increases when the thread is moved away from the flange-side travel end position. Included is a spooling device for carrying out the disclosed method.

A fishing line winder is disclosed. The line winder is combined with a line reel, so that a fishing line is sequentially reeled and unreeled. The line winder is a machine for preventing reverse winding and tangling, where a base of the fishing line winder is provided with a shaft, and a driving member drives the shaft to rotate, while a spindle is provided with a line spool, an abutment wheel and an unidirectional bearing; a resistance against the rotation of the abutment wheel is formed by means of a brake pad, thus preventing reverse winding and tangling when the fishing line is reeled onto and unreeled from the line reel.

A reel take-up apparatus includes a frame, a drive mechanism, a hydraulic counterbalance system, and a pair of positioning actuators. The frame may be configured to receive a reel from one end. The drive mechanism is generally slidably mounted to the frame and configured to rotate the reel. The hydraulic counterbalance system is generally configured to counterbalance a weight of the drive mechanism to allow the drive mechanism to float freely on the frame. The pair of positioning actuators may be configured to move a pair of support rollers toward and away from each other so as to (i) lift the reel from a support surface, (ii) support the reel during rotation by the drive mechanism, and (iii) lower the reel to the support surface for removal from the frame.

A reel take-up apparatus includes a frame, a drive mechanism, a hydraulic counterbalance system, and a pair of positioning actuators. The frame may be configured to receive a reel from one end. The drive mechanism is generally slidably mounted to the frame and configured to rotate the reel. The hydraulic counterbalance system is generally configured to counterbalance a weight of the drive mechanism to allow the drive mechanism to float freely on the frame. The pair of positioning actuators may be configured to move a pair of support rollers toward and away from each other so as to (i) lift the reel from a support surface, (ii) support the reel during rotation by the drive mechanism, and (iii) lower the reel to the support surface for removal from the frame.

A method for winding a cable (12) onto a cable reel (22) includes providing a cable reel (22) having a drum (24) arranged between two end flanges (28, 30). The drum (24) has a longitudinal axis (26), and the cable is placed (12) on the drum (24) to form a plurality of continuous helical windings (32) on the drum (24). Consecutive windings (32) are directly adjacent to each other, where main bending axes (34) of the continuous helical windings (32) and the longitudinal axis (26) of the drum (24) enclose an offset angle () greater than zero.

A method for winding a cable (12) onto a cable reel (22) includes providing a cable reel (22) having a drum (24) arranged between two end flanges (28, 30). The drum (24) has a longitudinal axis (26), and the cable is placed (12) on the drum (24) to form a plurality of continuous helical windings (32) on the drum (24). Consecutive windings (32) are directly adjacent to each other, where main bending axes (34) of the continuous helical windings (32) and the longitudinal axis (26) of the drum (24) enclose an offset angle () greater than zero.

Systems and methods are directed to a pull-through winding method, and a manufacturing fixture, or mandrel, that guides the layup of material in the pull-through winding method, for fabrication of a three-dimensional load bearing structure. These systems and methods allow fibers of material of the 3D load bearing structure to be pulled as straight as possible during winding, and maintained as straight as possible during curing, to take full advantage of properties associated with the fiber or filament-based materials used in these structures, including, for example, carbon fiber material. The manufacturing fixture includes a plurality of pull-through slots at end portions thereof, that provide for the pulling of the fiber-based material, and the application and maintenance of tension in the material that maintains the alignment of the fibers as the material is wound, cured and hardened.

Systems and methods are directed to a pull-through winding method, and a manufacturing fixture, or mandrel, that guides the layup of material in the pull-through winding method, for fabrication of a three-dimensional load bearing structure. These systems and methods allow fibers of material of the 3D load bearing structure to be pulled as straight as possible during winding, and maintained as straight as possible during curing, to take full advantage of properties associated with the fiber or filament-based materials used in these structures, including, for example, carbon fiber material. The manufacturing fixture includes a plurality of pull-through slots at end portions thereof, that provide for the pulling of the fiber-based material, and the application and maintenance of tension in the material that maintains the alignment of the fibers as the material is wound, cured and hardened.