A container may be provided. The container may comprise a first surface and a second surface concentric with the first surface. The first surface and the second surface may define a volume. The volume may house a concentric length of multiple parallel conductors. The multiple parallel conductors may pass through a restricting mechanism to restrict the multiple parallel conductors to pass at the same rate and at the same length.

A payout tube assembly is provided for unwinding filamentary material from a wound coil of filamentary material contained in a container having a wall panel with a hole that aligns with the payout tube assembly. The payout tube assembly includes a payout tube. The assembly also includes a generally planar payout panel affixed to the payout tube. The payout panel defines a central opening through which one end of the payout tube is received. In one embodiment, the payout panel defines a first set of arcuate slits and a second set of arcuate slits extending about the axis of the payout tube, the first and second sets of arcuate slits spaced radially and circumferentially from each other. In one embodiment, the payout panel defines radial slits extending from the central opening and defining payout panel fingers that are glued to the payout tube.

A payout tube assembly is provided for unwinding filamentary material from a wound coil of filamentary material contained in a container having a wall panel with a hole that aligns with the payout tube assembly. The payout tube assembly includes a payout tube. The assembly also includes a generally planar payout panel affixed to the payout tube. The payout panel defines a central opening through which one end of the payout tube is received. In one embodiment, the payout panel defines a first set of arcuate slits and a second set of arcuate slits extending about the axis of the payout tube, the first and second sets of arcuate slits spaced radially and circumferentially from each other. In one embodiment, the payout panel defines radial slits extending from the central opening and defining payout panel fingers that are glued to the payout tube.

Method of coiling a flexible elongate element (64) inside a container (80A) made from a flexible sheet material wherein at least part of the sheet material is tensioned by establishing a pressure differential between an inner surface (100) and an outer surface (92) of the sheet material and the flexible elongate element (64) is directed onto the tensioned sheet material to form a hole (98), the flexible elongate element being then fed through the hole to form a coil inside the container.

Method of coiling a flexible elongate element (64) inside a container (80A) made from a flexible sheet material wherein at least part of the sheet material is tensioned by establishing a pressure differential between an inner surface (100) and an outer surface (92) of the sheet material and the flexible elongate element (64) is directed onto the tensioned sheet material to form a hole (98), the flexible elongate element being then fed through the hole to form a coil inside the container.

Provided is a method for packing a cable having a static friction coefficient of 0.15 or more and 0.50 or less, a dynamic friction coefficient of 0.10 or more and 0.40 or less and a bending rigidity of 60 gf or more and 350 gf or less. The method includes the steps of: (1) winding the cable into a figure-of-eight shape to form a cylindrical cable bundle, (2) winding a wrapping film as a restraining member, which restrains the cable bundle, around an outer circumferential portion of the cable bundle, (3) winding a wrapping film as a closing member which closes openings on both ends of the cable bundle, and (4) housing the cable bundle being wound with the restraining member and the closing member in a housing container.

Provided is a method for packing a cable having a static friction coefficient of 0.15 or more and 0.50 or less, a dynamic friction coefficient of 0.10 or more and 0.40 or less and a bending rigidity of 60 gf or more and 350 gf or less. The method includes the steps of: (1) winding the cable into a figure-of-eight shape to form a cylindrical cable bundle, (2) winding a wrapping film as a restraining member, which restrains the cable bundle, around an outer circumferential portion of the cable bundle, (3) winding a wrapping film as a closing member which closes openings on both ends of the cable bundle, and (4) housing the cable bundle being wound with the restraining member and the closing member in a housing container.

A configuration and method for straightening a wire as the wire pays off from a bulk package. A bulk package hat is configured to be positioned over an opened bulk package containing wire bent in a helix shape. A bearing assembly is mounted inside the bulk package hat at a position where the wire exits the bulk package hat as the wire pays off from the bulk package. A wire straightening device has a plurality of rollers and only one single plane of straightening, and is configured to apply a counter bend to the wire as the wire pays off from the bulk package through the wire straightening device. The wire straightening device is operatively connected to the bearing assembly at an angle inside the bulk package hat. The bearing assembly and the single plane of straightening rotate, continually realigning with a current direction of the wire as it pays off.

A wire feeding system comprises a wire container including a box having an open upper side, and a wire container lid closing the upper side. The wire container lid includes a front wall having an opening through which wire is to be paid off. A wire outlet guide is attached to the front wall. The wire outlet guide comprises an upper and a lower hole for receiving the wire, the upper and lower holes being defined by a lower ring wall and an upper ring wall, respectively, and being distanced from each other in a wire feeding direction. At least the lower ring wall limits sideward movement of the wire and allows contact with the wire. The holes have a fixed position relative to the front wall. A deflection space bridging the distance between the holes allows sideward deflection of the wire between the ring walls.

A storage and feeding assembly for a wire to be fed to an apparatus having a drum suitable for storing the wire and extending about a drum axis between a resting base and an open upper end is provided. A wire handling device positioned between the drum and the apparatus is suitable for extracting the wire from the drum to feed the wire to the apparatus. A lid, placed above the drum and having an upper lid wall in which an outlet passage for the wire is provided, and a lid side wall define a lid volume. The wire handling device extends into the lid volume substantially coaxially to the drum axis.