A textile machine and associated operational method are provided, wherein the textile machine has a plurality of workstations for (a) delivering a thread to a bobbin, (b) laying the thread on the bobbin, (c) winding the thread on the bobbin, and (d) finding a thread end wound on the bobbin with a suction nozzle. The thread is run through the suction nozzle during delivery to the bobbin such that the thread enters an inlet mouth in the suction nozzle and exits the suction nozzle through an extraction mouth. Starting from a thread delivery device at the workstation, the thread is run freely until the thread enters the inlet mouth of the suction nozzle directly in front of the bobbin. For finding of the thread end wound on the bobbin, the thread end is sucked into the suction nozzle through the extraction mouth.

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 fiber laser system comprises a main body, wherein the main body includes one or more fiber laser system components and a first wall hingedly attached to the main body along a first edge, the first wall having a first wall open position and a first wall closed position and a plurality of feed fiber management and splicing components mounted to the first wall. Additionally and/or alternatively, the laser system may comprise a cooling plate hingedly attached to the main body, the cooling plate has a cooling plate open position and a cooling plate closed position. Additionally and/or alternatively, the laser system may include a fiber management tray hingedly mounted to the cooling plate, the fiber management tray having a fiber management tray open position and a fiber management tray closed position.

A cable feed device for feeding a cable to a cable processing machine includes a first rotatable roller and a second rotatable roller for guiding the cable such that the cable can be arranged in a loop around the first roller and the second roller, and a cable drive for transporting the cable. The first roller is arranged stationary, wherein the second roller can be pushed or pulled away from the first roller with a force, wherein the second roller has a first state and a second state, wherein the second roller is locked in a first position in the first state and is moved in the second state by the force such that the distance between the first roller and the second roller changes depending on the length of the cable between the two rollers.

The invention relates to a machine (100) for manufacturing an optical fibre (200), characterised in that the machine comprises: at least one capstan (20, 21) and at least one pulley (22), which define a run of the optical fibre in a main area (2) of the machine, an optical fibre guiding system comprising a transmission member (25) and a clamping element (26) that is rigidly connected to the transmission member (25) and is able to retain an end of the optical fibre (200), the transmission member (25) being arranged parallel to the run of the optical fibre, a device (5) for having the clamping element (26) automatically grip the optical fibre (200), said device comprising: means (53) for placing the optical fibre in a starting position in which the optical fibre runs at a distance from the clamping element in a direction extending substantially perpendicularly to the clamping element (26), a fibre-spacing finger (51), that can move between a neutral position at a distance from the optical fibre located in the starting position and a position in which the finger (51) keeps the optical fibre at a distance from the starting position in such a way as to bring the optical fibre into an intermediate position opposite the clamping element (26), said means being designed to open the clamping element (26) when the finger (51) has brought the optical fibre (200) into the intermediate position and close the clamping element again when the finger (51) has returned to the neutral position thereof.

A fiber laser system comprises a main body, wherein the main body includes one or more fiber laser system components and a first wall hingedly attached to the main body along a first edge, the first wall having a first wall open position and a first wall closed position and a plurality of feed fiber management and splicing components mounted to the first wall. Additionally and/or alternatively, the laser system may comprise a cooling plate hingedly attached to the main body, the cooling plate has a cooling plate open position and a cooling plate closed position. Additionally and/or alternatively, the laser system may include a fiber management tray hingedly mounted to the cooling plate, the fiber management tray having a fiber management tray open position and a fiber management tray closed position.

The method in accordance with the invention for a textile machine, in particular a spinning or a winding machine with multiple similar workstations (1), serves the purpose of delivering a thread (7) to a coil (12), laying the thread (7) on the coil (12), for winding the thread (7) on the coil (12) and for finding a thread end wound on the coil (12) by means of a suction nozzle (4), whereas the thread end is sucked in by means of an opening turned towards the coil circumference that serves as an extraction mouth (10) of the suction nozzle (4). The thread (7) runs through the suction nozzle (4) during the delivery to the coil (12), whereas it enters through an additional opening in the suction nozzle (4) serving as an inlet mouth (9) for the thread (7) and exits the suction nozzle (4) through another opening, in particular through the extraction mouth (10). A textile machine, in particular a spinning or a winding machine, features multiple similar workstations, in each case with a thread delivery device for delivering a thread (7) to a coil (12), a thread traversing device for laying the thread (7) on the coil (12), a winding device for winding the thread (7) on the coil (12) and a suction nozzle (4) for finding a thread end wound on the coil (12), whereas the suction nozzle (4) features an opening turned towards the coil circumference that serves as an extraction mouth (10) for sucking in the thread end. The suction nozzle (4) features an additional opening serving as an inlet mouth (9) for the thread (7), and the thread (7) runs through the suction nozzle (4) during the delivery to the coil (12), whereas it enters the suction nozzle (4) through the inlet mouth (9), and exits the suction nozzle (4) through another opening, in particular the extraction mouth (10).

Thread-guiding device for a workstation of a textile machine which produces cross-wound bobbins. The workstation has an unwinding aid device for feed bobbins, a winding device for producing a cross-wound bobbin and a thread-guiding channel which surrounds the thread path and which can be subjected to negative pressure. The thread-guiding device is installed at the end face of the thread-guiding channel in the region of a suction head above the regular thread path in the workstation and is designed such that during a thread cutting process initiated during the winding operation, the thread end of the newly created upper thread, said thread end shooting upwards as a result of the thread tension in the running thread, enters the thread-guiding device and is guided in a controlled manner by the thread-guiding device in the direction of the center of the cross-wound bobbin.

A system for transporting fiber ends can comprise a fiber supply assembly that supplies fiber along a first axis. A plurality of eyeboards can be positioned along the first axis. Each eyeboard can define a plurality of openings therethrough. Each opening of the plurality of openings can be configured to receive therethrough a fiber from the fiber supply assembly. A track can extend along the first axis. The track can pass proximate to each eyeboard of the at least one eyeboard. A carriage can be movable along the track. The carriage can define at least one fiber attachment element. An actuator can be configured to move the carriage along the track.

A wire feeder includes a cartridge disposed in a supply position and having a wire spool wound with a wire, and including an outlet portion through which the wire is drawn outwardly along an internal travel path, an air guide disposed on a wire supply path and including a first inlet portion through which the wire drawn out from the outlet portion is drawn in, wherein the first inlet portion is aligned with the outlet portion on the wire supply path, a sensor disposed at the first inlet portion of the air guide, and a first vacuum line generating a vacuum in an interior of the first inlet portion according to a detection of the wire at the first inlet by the sensor.