The invention relates to the use of a yarn spool handling container (1) for a yarn spool (2). The yarn spool handling container (1) comprises a frame or a housing (6). With respect to the frame or housing (6), a spindle (15) is rotatably supported. In the yarn spool handling container (1) a winding and unwinding of the technical yarn occurs. The yarn spool (2) is arranged in the yarn spool handling container (1) even during stocking and transport.

The invention relates to the use of a yarn spool handling container (1) for a yarn spool (2). The yarn spool handling container (1) comprises a frame or a housing (6). With respect to the frame or housing (6), a spindle (15) is rotatably supported. In the yarn spool handling container (1) a winding and unwinding of the technical yarn occurs. The yarn spool (2) is arranged in the yarn spool handling container (1) even during stocking and transport.

A spool winder. The spool winder includes a plurality of arms, each having an upper end and a lower end. The plurality of arms are pivotally affixed at the lower end about a rod, wherein the rod can removably secure to a power drill. A notch is disposed on the upper end such that the notch faces the rod, wherein the notch can receive a rim of a spool therein. The spool winder further includes a slide lock having a plurality of apertures therein, wherein the plurality of apertures can receive the plurality of arms therethrough. The plurality of arms can move between a closed position and an open position as the slide lock is moved from the upper end towards the lower end. The distance between the upper end of each of the plurality of arms and the rod is greater when the arms are in the open position.

Implementations of a tape holder are provided. In some implementations, the tape holder may be used to secure a roll of tape to a magnetic surface. In some implementations, the tape holder is comprised of a base member and a spool support.

Implementations of a tape holder are provided. In some implementations, the tape holder may be used to secure a roll of tape to a magnetic surface. In some implementations, the tape holder is comprised of a base member and a spool support.

A winding machine (1) for a traversing application of a winding material (51) to a spool sleeve (27) comprises a spindle (8) which is supported for being rotated and for having a fixed axial position. The spindle (8) comprises an inner recess. The winding machine (1) comprises a drive driving the spindle (8) for a rotational movement and a traversing carriage (20). The traversing carriage (20) is supported on the spindle (8) for being movable with a traversing motion (18) in an axial direction relative to the spindle (8). A first coupling element serves for transmitting the rotational movement of the spindle (8) to the traversing carriage (20) and a second coupling element serves for transmitting the traversing motion (18) of the traversing carriage (20) to the spool sleeve (27). The winding machine (1) also comprises an actuation mechanism (30) executing the traversing motion (18). The actuation mechanism (30) is coupled to the traversing carriage (20) for transmitting the traversing motion (18) from the actuation mechanism (30) to the traversing carriage (20). The actuation mechanism (30) extends through the inner recess of the spindle (8).

Quick-adjust tensioner that exerts a braking torque on a spool. The tensioner includes a stop configured to fit onto a rod supporting the spool. The location of the stop on the rod is adjustable by the user. The stop is connected to a foot by a biasing member. The biasing member presses the foot against the spool to create a braking torque on the spool. The force of the biasing member on the foot is predetermined by adjusting the distance between the stop and the foot, thereby adjusting the foot's braking torque on the spool.

A spool fixation device for use in a wire winding installation, where in this spool fixation device, spools having a magnetically attractable flange are held to a rotatable flange using magnet assemblies. The magnet assemblies can be switched between a hold state and a release state. In a preferred embodiment the magnet assemblies only consume energy when in the release state i.e. when the spool fixation device is not rotating. Alternatively the magnet assemblies can be made to only consume energy when switching states. The magnet assemblies have permanent magnet arrays and are moveable inside a non-magnetic housing. Also a drive pin to transfer torque between rotatable flange and spool is no longer necessary. Therefore the spool fixation devices allows for a smooth changeover of spools.

A capstan includes a lift motor, a flexible lifting member, and a tether assembly. The lift motor is operatively connected to a shaft. The flexible lifting member includes a first end and a second end. The first end is connected to the shaft. The flexible lifting member connects a lift assembly to the lift motor via the shaft. The tether assembly includes a switch arranged between a portion of the flexible lifting member and a portion of the capstan. The second end is connected to the tether assembly. The switch acts as a safety in case of a broken flexible lifting member and allows for an automated unloading cycle.

A capstan includes a lift motor, a flexible lifting member, and a tether assembly. The lift motor is operatively connected to a shaft. The flexible lifting member includes a first end and a second end. The first end is connected to the shaft. The flexible lifting member connects a lift assembly to the lift motor via the shaft. The tether assembly includes a switch arranged between a portion of the flexible lifting member and a portion of the capstan. The second end is connected to the tether assembly. The switch acts as a safety in case of a broken flexible lifting member and allows for an automated unloading cycle.