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 device is disclosed for managing at least one flexible cable including a rigid portion. In at least one embodiment the device includes a first axial end and a second axial end distanced from one another along an axis of the device; at least a first winding surface at the first axial end and at least a second winding surface at the second axial for receiving at least first coil and a second coil of the flexible cable, the first and second winding surfaces being transversal with respect to the axis; and a constraint in the form of a clip or a cylindrical surface for supporting the rigid portion of the flexible cable between the first and the second axial end.

A device is disclosed for managing at least one flexible cable including a rigid portion. In at least one embodiment the device includes a first axial end and a second axial end distanced from one another along an axis of the device; at least a first winding surface at the first axial end and at least a second winding surface at the second axial for receiving at least first coil and a second coil of the flexible cable, the first and second winding surfaces being transversal with respect to the axis; and a constraint in the form of a clip or a cylindrical surface for supporting the rigid portion of the flexible cable between the first and the second axial end.

An apparatus for reducing fiber whip damage to optical fiber wound on a fiber winding spool is provided. The apparatus includes a fiber entry feed mechanism operatively coupled to the fiber winding spool to feed the optical fiber onto the fiber winding spool. The apparatus also includes a whip shield arranged to substantially surround the fiber winding spool. The whip shield includes a first surface aligned with and facing the fiber winding spool within an entry slot that is laterally offset from a second surface. The first surface transitions to the second surface such that a loose end of the optical fiber is initially directed into the entry slot away from the fiber winding spool and transitions to the second surface.

An apparatus for reducing fiber whip damage to optical fiber wound on a fiber winding spool is provided. The apparatus includes a fiber entry feed mechanism operatively coupled to the fiber winding spool to feed the optical fiber onto the fiber winding spool. The apparatus also includes a whip shield arranged to substantially surround the fiber winding spool. The whip shield includes a first surface aligned with and facing the fiber winding spool within an entry slot that is laterally offset from a second surface. The first surface transitions to the second surface such that a loose end of the optical fiber is initially directed into the entry slot away from the fiber winding spool and transitions to the second surface.

A textile machine includes a protective exterior cover, a slotted yarn access formed in the protective cover, and a safety guard shielding at least a portion of the slotted yarn access. The safety guard includes a guard body mounted to the protective cover proximate the slotted yarn access. The guard body has a fastener edge residing adjacent a first side of the slotted yarn access, and a free edge residing adjacent a second side of the slotted yarn access. The free edge of the guard body extends above and across the slotted yarn access and forms an unobstructed space on the second side of the slotted yarn access allowing yarn to pass around the free edge, underneath the safety guard and through the protective cover.

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 yarn feeder may comprise a metric-sized motor and a winding wheel, and a drive shaft axially protruding from a first end of the motor is configured to connect to a rotating member. The winding wheel formed in a tube shape comprises a first end and a second end, and an interior channel is adapted to axially penetrate through the winding wheel from the first end to the second end thereof. The interior channel is configured to accommodate the motor, and the rotating member is coupled with the interior channel such that the motor is configured to drive the winding wheel through the rotating member. The motor in the present invention is a metric-sized motor which is not only easy to buy in the market but also reduces manufacturing cost and the volume of the yarn feeder.

A yarn feeder may comprise a metric-sized motor and a winding wheel, and a drive shaft axially protruding from a first end of the motor is configured to connect to a rotating member. The winding wheel formed in a tube shape comprises a first end and a second end, and an interior channel is adapted to axially penetrate through the winding wheel from the first end to the second end thereof. The interior channel is configured to accommodate the motor, and the rotating member is coupled with the interior channel such that the motor is configured to drive the winding wheel through the rotating member. The motor in the present invention is a metric-sized motor which is not only easy to buy in the market but also reduces manufacturing cost and the volume of the yarn feeder.