The invention has as its object a method for packing a welding wire (25) inside a container (40) which includes at least the following steps:

a feeding phase of said welding wire (25) inside a tube (13) placed in rotation to produce a prefixed torsion at each wire loop (25);

a winding phase of the wire (25) coming out of said tube in rotation (13) on a core (20) configured to wind said wire (25) on it, said core (20) being provided with an alternative movement in a substantially vertical direction;

a wire cutting phase (25) at the end of said wire winding phase on the core to (20) and;

a core pick-up phase with the wire (25) wound on it and a core introduction phase (20) with the wire (25) wound on it inside a container (40).

The present invention is an oscillating traverse coiler for flexible elongated materials apparatus, system, and method for use. The invention may include a reel having a first flange, a second flange, and a barrel between. The invention may include a take-up machine having a computer control that works in communication with a positioning system, which may include a frame, guide rails that traverse the frame with a motor, a computer controller, and a rotating materials guide for rotating pipe flexible elongated materials on the barrel of a reel.

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).

A filament winding apparatus winds, around a workpiece, a fiber bundle formed by bundling a plurality of fibers. The filament winding apparatus includes a widening roller that rotates while making contact with the fiber bundle that is being conveyed. The widening roller has, provided on the peripheral surface, a plurality of projecting ridges extending in the axial direction, the projecting ridges being arranged side by side in the circumferential direction. The projecting ridges make contact with the fiber bundle to thereby widen the fiber bundle.

A cable coiling system for coiling a cable into a cable coil includes a reel rotatable around a central axis of the reel, a gripper configured to grip a starting end of the cable, and a slide rail extending in a direction perpendicular to the central axis of the reel. The cable is coilable around the reel to form the cable coil by rotating the reel in a state in which the gripper is coupled onto the reel and grips the starting end of the cable. The reel is slidably mounted on the slide rail. A length of the starting end of the cable coiled around the reel is adjustable by moving the reel along the slide rail and rotating the reel around the central axis in a state in which the gripper is separated from the reel and fixed at a predetermined position.

A method of winding an optical fiber includes winding the optical fiber using a bobbin that includes: a body portion having two end portions; and a pair of flanges, respectively disposed at the end portions in an axial direction of the body portion. An inner surface of each of the flanges is inclined toward an outer side in the axial direction and toward a radial outer side. The method further includes guiding the optical fiber to the bobbin using a final pulley. The bobbin and the final pulley reciprocate relative to each other in the axial direction at a traverse speed V (mm/sec) such that 0.0050≤θ (rad)≤0.1000, where θ is a delay angle, θ=arctan (V/L), and L (mm) is a distance from a winding position of the optical fiber at the bobbin to the final pulley in a radial direction.

A filament winding apparatus winds, around a workpiece, a fiber bundle formed by bundling a plurality of fibers. The filament winding apparatus includes a widening roller that rotates while making contact with the fiber bundle that is being conveyed. The widening roller has, provided on the peripheral surface, a plurality of projecting ridges extending in the axial direction, the projecting ridges being arranged side by side in the circumferential direction. The projecting ridges make contact with the fiber bundle to thereby widen the fiber bundle.

An improved winding apparatus and system for winding strips of web materials.

A cable coiling system for coiling a cable into a cable coil includes a reel rotatable around a central axis of the reel, a gripper configured to grip a starting end of the cable, and a slide rail extending in a direction perpendicular to the central axis of the reel. The cable is coilable around the reel to form the cable coil by rotating the reel in a state in which the gripper is coupled onto the reel and grips the starting end of the cable. The reel is slidably mounted on the slide rail. A length of the starting end of the cable coiled around the reel is adjustable by moving the reel along the slide rail and rotating the reel around the central axis in a state in which the gripper is separated from the reel and fixed at a predetermined position.

A process and apparatus for separating a carbon filament tow into a set of reduced filament count bundles. The process includes feeding a tow of carbon filaments into a guide array, mechanically splitting the tow within the guide array into filament bundles, removing a coating from the filament bundles, feeding the filament bundles into a guide pin assembly to separate the filament bundles with a reduced filament count from one another, applying a false twist to the filament bundles to loosen individual filaments then recombining the individual filaments of each filament bundle into a re-bundled ribbon. Coatings may be applied to each re-bundled ribbon prior to winding each re-bundled ribbon onto a take-up.